The present disclosure relates generally to electric heaters, and more particularly to electric heaters with a more uniform structure and more uniform heating performance and methods of manufacturing same.
The statements in this section merely provide background information related to the present disclosure and may not constitute prior art.
Some forms of electric heaters having a layered construction generally include a substrate, a dielectric layer disposed on the substrate, a resistive heating layer disposed on the dielectric layer, and a protective layer disposed on the resistive heating layer. The dielectric layer, the resistive heating layer, and the protective layer may be broadly called “functional layers.” One or more of the functional layers of the electric heaters may be in the form of a film by depositing a material onto a surface or a substrate.
On a microscopic scale, a deposited film may have an uneven surface due to existing features or trenches on the substrate surface. A top surface of the deposited film generally undergoes a planarization process in order to flatten the top surface and to provide more uniform performance of the functional layer. However, the planarization process may undesirably remove excessive material from the deposited film, causing the thickness of the final deposited film to deviate from its designed thickness. Moreover, when the deposited film is a dielectric layer with an electrical element embedded therein, the dielectric integrity of the film may be compromised due to the reduced thickness of the dielectric layer, resulting in poor performance of the electric heater.
These issues related to the design and performance of electric heaters is addressed by the present disclosure.
In one form, a method of constructing a heater is provided. The method includes the steps of forming a sintered assembly including a ceramic substrate and a plurality of first slugs embedded therein, forming a functional element on one of opposing surfaces of the sintered assembly such that the functional element is connected to the plurality of first slugs, and forming a monolithic substrate in which the functional element and the plurality of first slugs are embedded.
In another form, a method of constructing a heater includes the step of forming a sintered assembly including a ceramic substrate and a plurality of first slugs embedded therein, forming at least one trench into one of the opposing surfaces of the sintered assembly and into a part of the plurality of first slugs, depositing a functional material into the at least one trench to form a functional element such that the functional element is connected to the plurality of first slugs, applying a material layer on the other one of the opposing surfaces of the functional element, the material layer being connected to the first slugs, and forming a monolithic substrate in which the functional element, the first slugs, and the material layer are embedded.
Further areas of applicability will become apparent from the description provided herein. It should be understood that the description and specific examples are intended for purposes of illustration only and are not intended to limit the scope of the present disclosure.
The present disclosure will become more fully understood from the detailed description and the accompanying drawings, wherein:
Corresponding reference numerals indicate corresponding parts throughout the several views of the drawings.
The following description is merely exemplary in nature and is not intended to limit the present disclosure, application, or uses.
Referring to
The heater layer 12 includes a substrate 18 defining at least one trench 20, and at least one resistive heating element 22 disposed in the trench 20. When a plurality of trenches 20 are formed in the substrate 18, a plurality of resistive heating elements 22 may be disposed in the plurality of trenches 20 to define a plurality of heating zones. The trench 20 may define a plurality of first trench sections 21 and at least two second trench sections 24 having an enlarged trench area for electrical termination. The trench 20 defines a depth of about 1 to 10 microns, preferably a depth of about 3 to 5 microns.
The resistive heating element 22 includes at least two terminal pads 26 disposed in the second trench sections 24 having enlarged trench areas. The resistive heating element 22 has a resistive material selected from the group consisting of molybdenum, tungsten, platinum, or alloys thereof. In addition, the resistive material of the resistive heating element 22 may have sufficient temperature coefficient of resistance (TCR) characteristics such that the resistive heating element 22 functions as a heater and as a temperature sensor.
The heater layer 12 further includes a pair of terminal pins 28 in direct contact with the terminal pads 26 of the resistive heating element 22 and extending from the terminal pads 26 through the substrate 18 and the bonding layer 16 to the routing layer 14.
The routing layer 14 includes a substrate 30 defining at least one trench 32, and a routing element 34 disposed in the trench 32. One or more routing elements 34 may be provided depending on applications. The routing element 34 functions to connect the resistive heating elements 22 of the heater layer 12 to an external power source (not shown). The trench 32 of the routing layer 14 may include at least two trench sections 33 corresponding to the second trench sections 24 of the trench 20 of the heater layer 12. The routing layer 14 further includes a pair of terminal pins 36 located in the at least two trench sections 33 and extending from the routing element 34 through the substrate 30 and beyond a lower surface 38 of the substrate 30. The terminal pins 36 of the routing layer 14 are aligned with and in contact with the terminal pins 28 of the heater layer 12.
The substrate 18 of the heater layer 12 and the substrate 30 of the routing layer 14 may include a ceramic material, such as aluminum nitride and aluminum oxide.
Referring to
In the sub-process of manufacturing the heater layer 12, a substrate 18 in a blank form is provided in step 102. The substrate 18 has opposing first and second surfaces 40 and 42. A hard mask layer 46 is formed, such as by deposition, on the first surface 40 in step 104.
Next, a photo resist layer 48 is deposited on the hard mask layer 46 in step 106. The photo resist layer 48 is etched to form a photo resist pattern 50 on the hard mask layer 46 in step 108. In this step, a photo mask (not shown) for patterning the photo resist layer 48 is placed above the photo resist layer 48, and an ultraviolet (UV) light is applied onto the photo resist layer 48 through the photo mask to develop the portions of the photo resist layer 48 that are exposed to the UV light, followed by etching the exposed portion or the unexposed portions of the photo resist layer 48 to form the photo resist pattern 50. The photo resist pattern 50 may be a positive pattern or a negative pattern depending on whether the exposed or unexposed portions of the photo resist layer 48 are etched and removed.
Referring to
Next, an etching process is performed on the first surface 40 of the substrate 18 by using the hard mask pattern 52 as a mask to form at least one trench 20 in the substrate 18 in step 114. The trench 20 defines a plurality of first trench sections 21 and at least two second trench sections 24 having enlarged areas. The at least two second trench sections 24 correspond to the at least two enlarged openings 54 of the hard mask pattern 52. The at least one trench 20 may be formed by a laser removal process, machining, 3D sintering/printing/additive manufacturing, green state, molding, waterjet, hybrid laser/water, dry plasma etching.
After the trench 20 is formed in the substrate 18, the hard mask pattern 52 is removed and the substrate 18 is cleaned to form a substrate 18 with a trench 20 with a desired trench pattern on the first surface 40 of the substrate 18 in step 116.
The number of the trenches 20 and the number of the enlarged second trench sections 24 depend on the number of heating zones of the resistive heating element 22 to be formed in the trench 20. The depth and width of the first and second trench sections 21 and 24 of the trench 20 depend on the desired function and performance of the resistive heating element 22. For example, when only one trench 20 is formed in the substrate 18, the trench 20 may have a constant or varied depth and/or width. When a plurality of trenches 20 are formed in the substrate 18, some of the trenches 20 may be wider and the others may be narrower; some of the trenches 20 may be deeper and the others may be shallower.
Referring to
At step 120, a pair of terminal pins 28 are inserted into the via holes 64 and extend through the substrate from the pad opening 62 past the second surface 42 of the substrate 18. Each terminal pin 28 includes a terminal end 26 disposed in the pad opening 62 between the via hole 64 and the enlarged second trench section 24.
Thereafter, a resistive material 66 is deposited on the first surface 40 of the substrate 18 and in the trench 20 in step 122. As an example, the resistive material 66 may be formed on the substrate 18 and in the trench 20.
The resistive material 66 is thermally treated in step 124. As an example, the substrate 18 with the resistive material 66 disposed both in the trench 20 and on the first surface 40 of the substrate 18 may be placed in a furnace for annealing.
Referring to
Finally, a protective layer 17 is formed on the first surface 40 of the substrate 18 and the top surface 67 of the resistive heating element 22 in step 128. The protective layer 17 electrically insulates the resistive heating element 22. The protective layer 17 may be formed on the substrate 18 by bonding a preformed protective layer to the substrate 18. The bonding process may be a brazing process or a glass frit bonding. Alternatively, when multiple trenches 20 are formed in the substrate 18, some of the trenches 20, preferably the trenches located around periphery of the substrate 18, may be filled with a bonding agent so that the bonding agent in some of the trenches 20 may bond the substrate 18 to the protective layer 17. After the protective layer 17 is formed on the substrate 18, a heater layer 12 is completed.
As previously described, the depth and width of the trench 20 may be configured to be varied along the length of the trench 20. With varied depth and width, the trench 20 allows the resistive heating element 22 to be formed with varied thickness and width along its length, thereby achieving variable wattage along the length of the resistive heating element 22. Moreover, by using the trench 20 to define the shape of the resistive heating element 22, it is possible to deposit different materials in different portions of the same trench, or to deposit two or more layers of materials in the same trench 20. For example, a resistive material may be deposited in the trench 20 first, followed by depositing a bonding agent on top of the resistive material. Therefore, the materials in the trench 20 can also be used as a bonding agent to bond a protective layer thereon. Engineered layers or doped materials may also be deposited in different portions of the trench 20 to achieve a resistive heating element having different material properties along its length.
Referring to
More specifically, the sub-process of manufacturing the routing layer 14 includes steps similar to step 102 through step 126 as previously described in connection with
Moreover, the substrate 30 of the routing layer 14 has a trench 32 having a trench pattern different from that of the trench 20 of the substrate 18 of the heater layer 12. As shown in
Referring to
Next, the routing element 34 is machined to define a pair of via holes 68 extending from a top surface of the routing element 34 to the terminal ends 69 in step 132. Thereafter, the heater layer 12 is placed on top of the routing layer 14 in step 134. The terminal pins 28 of the heater layer 12 that extend beyond the second surface 42 of the substrate 18 are inserted into the via holes 68 so that the terminal pins 28 of the heater layer 12 are in contact with the terminal end 69 of the routing layer 14. Therefore, the resistive heating element 22 of the heater layer 12 is electrically connected to the routing element 34, which in turn, is electrically connected to an external power source.
Referring to
The method 200 starts with providing a substrate 70, and forming at least one trench 72 into the substrate 70 in step 202. The substrate 70 may include aluminum nitride. In this step, the at least one trench may be formed by a mechanical method, such as a laser removal/cutting process, micro bead blasting, machining, 3D sintering/printing/additive manufacturing, green state, molding, waterjet, hybrid laser/water, or dry plasma etching without using a hard mask pattern. When a micro bead blasting process is used, the particle size of the beads is less than 100 μm, preferably less than 50 μm.
Next, a first functional material 74, which includes a first metal, is filled in the trench 72 and on a top surface of the substrate 70 in step 204. The first functional material 74 may be formed by a layered process, which involves application or accumulation of a material to a substrate or another layer using processes associated with thick film, thin film, thermal spraying, or sol-gel, among others. Alternatively, the first functional material 74 may be deposited on the substrate 70 and in the trench 72 using a braze reflow process, as previously described in connection with step 122 of
Next, similar to step 124 described in connection with
Next, at least one via 79 is formed through the dielectric layer 78 at at least two corresponding locations to expose a portion of the first functional element 76 in step 210. The via 79 may include a via hole 80 and a trench 82. This step includes a step of forming a trench 82 in the dielectric layer 78, and a step of forming a via hole 80 through the dielectric layer 78 and into the first functional element 76. The trench 82 may be formed before or after the via hole 80 is formed. The via 79 may be formed by laser cutting. The trench 82 may have a depth in the range of approximately 100 nm to 100 μm.
A second functional material 84 is deposited into the via 79 including the via hole 80 and the trench 82 and a top surface of the dielectric layer 78 so that the second functional material 84 is in contact with the first functional element material 76 in step 212.
Excess second functional material 84 is removed from the dielectric layer 78, thereby leaving the second functional material 84 within the via 79 to form electrical terminations to the first functional element 76 in step 214. In this step, the second functional material 84 remaining in the trench 80 forms a second functional element 86. The top surface of the second functional material 84 after the removing step is flush with the top surface of the dielectric layer 78. Alternatively, the second functional material 84 may be etched to form a desired profile.
When the method 200 is used to form an electric heater, the first functional element 76 may be a resistive heating element and the second functional element 86 may be a routing element for connecting the resistive heating element to an external power source. When the method 200 is used to form an electrode layer of an electrostatic chuck, the first functional element 76 may be an electrode element and the second functional element 86 may by a routing element for connecting the electrode element to an external power source.
Alternatively, the first functional element 76 may be configured to be a routing element, whereas the second functional element may be configured to be a resistive heating element, or an electrode element. In this case, the via hole 80 may be filled with the same material of the first functional element 76 or a different material for a desired electrical conduction.
Thereafter and optionally, a first post hole 90 or a second post hole 92 may be formed in step 216. The first post hole 90 extends through the dielectric layer 92 and the underlying first functional element 76. The second post hole 92 extends through the second functional element 86. The first and second post holes 90 and 92 may be formed by a laser cutting process or a bead blasting process.
Additional terminal pins (not shown) may be inserted into the first post hole 90 and/or the second post hole 92 for connecting the first functional element 76 and/or the second functional element 86 to another electrical component, such as another heater layer, a tuning layer, a temperature sensing layer, a cooling layer, an electrode layer, and/or an RF antenna layer. As a result, the additional heater layer, tuning layer, cooling layer, electrode layer, or RF antenna layer can be connected to the same routing element and to an external power source. The additional heater layer, tuning layer, cooling layer, electrode layer, RF antenna layer may be manufactured by the methods 100 or 200 described in connection with
With respect to the method 100 disclosed in connection with
Alternatively, the sub-process of manufacturing the heater layer 12 may be used to form another electrical component by filling a different material in the trench. For example, a cooling layer may be formed if a Peltier material fills in the trench of the substrate. An electrode layer for an electrostatic chuck may be formed if an electrode material fills in the trench. An RF antenna layer may be formed if a suitable RF antenna material fills in the trench. A thermal barrier layer may be formed if a material with relatively low thermal conductivity fills in the trench. A thermal spreader may be formed if a material with relatively high thermal conductivity fills in the trench.
The electric heater 10 manufactured by the methods 100, 200 of the present disclosure has an embedded heating circuit and an embedded routing circuit, and a plurality of functional layers that are more planar throughout the substrate. Therefore, the electric heater can have a more uniform structure and more uniform heating performance.
Referring to
In the illustrative form, the plate assembly 302 is an electric heating plate and includes a ceramic substrate 308, a resistive heating element 310, and a routing element 312. The resistive heating element 310 and the routing element 312 are embedded in the ceramic substrate 308. The ceramic substrate 308 is a monolithic substrate formed by hot pressing and may be made of a ceramic material, such as aluminum nitride (AlN) and aluminum oxide (Al2O3). The plate assembly 302 further includes a plurality of first termination portions 314 for electrically connecting the resistive heating element 310 to the routing element 312, and a pair of second termination portions 316 disposed adjacent to a central portion of the routing element 312. A pair of lead wires 318 are connected to the second termination portions 316 and extend inside the tubular shaft 304 for connecting the routing element 316 to an external power supply (not shown). The number of the first termination portions 314 depend on the number of heating zones defined by the resistive heating element 310.
The resistive heating element 310 is made of a resistive material having relatively high resistivity, such as one selected from the group consisting of molybdenum, tungsten, platinum, or alloys thereof, in order to generate heat. In addition, the resistive material of the resistive heating element 310 may have sufficient temperature coefficient of resistance (TCR) characteristics such that the resistive heating element 22 functions as a heater and as a temperature sensor. The routing element 312 is made of a conductive material having relatively high conductivity to electrically connect the resistive heating element 310 to an external power source.
It is understood that when the plate assembly 302 is formed as an electrostatic chuck, an electrode element, in place of the resistive heating element, may be formed.
Referring to
Next, the hot isostatic press chamber 450 (only shown in step 402) is filled with ceramic powder 455, such as AlN powder, in step 404. Then, the ceramic powder 455 and the first and second slugs 452, 454 undergo a hot pressing process in the hot isostatic press chamber 450 to form a sintered assembly 456 in step 406. Hot pressing is known as a high-pressure, low-strain-rate powder metallurgy process for forming a powder compact at a temperature high enough to induce sintering and creep processes. This is achieved by simultaneous application of heat and pressure. In the sintered assembly 456, the first and second slugs 452, 454 are pressed, sintered, and embedded in a ceramic substrate 457. The sintered assembly 456 has a first surface 458 and a second surface 460. The first slugs 452 extend from the first surface 458 to the second surface 460 and are exposed from the first and second surfaces 458 and 460. The second slugs 454 are exposed to only the second surface 460. Lapping may be applied on the sintered assembly 456 to achieve a high level of surface flatness and parallelism.
Referring to
Next, a functional material 464 is applied on the first surface 458 of the sintered assembly 456 to fill the trench 462 and to cover the entire first surface 458 in step 410. The functional material 464 may be applied by deposition or sputtering, or any conventional methods. Alternatively, the functional material 462 may be formed by a layered process, which involves application or accumulation of a material to a substrate or another layer using processes associated with thick film, thin film, thermal spraying, or sol-gel, among others. Alternatively, the functional material 462 may be deposited on the sintered assembly 456 and in the trench 462 using a braze reflow process. For example, the functional material 464 may be formed by placing a metallic foil on the first surface 458 of the sintered assembly 465, followed by melting the metallic foil so that the molten material may fill in the trench 462 and reflows to the first surface 458 of the sintered assembly 456.
The functional material 464 may be a resistive material having relatively high resistivity, such as molybdenum, tungsten, platinum, or alloys thereof. If an electrostatic chuck is desired, the functional material 464 may be a material suitable for an electrode. Next, a planarization process is performed on the functional material 464 to remove excess functional material until the first surface 458 is exposed, thereby forming a functional element in the trench 20 in step 412. In this form, the functional element is a resistive heating element 310, which is connected to the first slugs 452. The planarization process may be a chemical mechanical polishing/planarization (CMP) process, etching, polishing.
Thereafter, a sintered substrate part 470 is placed in the hot isostatic press chamber 450 and the sintered assembly 456 is placed on top of the second sintered plate 470 with the resistive heating element 310 disposed adjacent to the sintered substrate part 470 in step 414. Alternatively, instead of using a sintered substrate part 470, another sintered assembly with another functional element embedded therein may be used to be bonded to the sintered assembly 456 depending on applications. Optionally, a mixture 472 of AlN powder and sintering aide may be applied between the sintered assembly 456 and the sintered substrate part 470 to facilitate bonding the sintered assembly 456 to the sintered substrate part 470.
Referring to
Next, the sintered assembly 456, the sintered substrate part 470, and the mixture 478 of AlN powder and sintering aid undergo the hot pressing process in the isostatic press chamber 450 in step 418. A single monolithic substrate 308 is thus formed, with the resistive heating element 310, the routing element 312 (i.e., the material layer 476), the first and second terminations 314, 316 (i.e., the first and second slugs 452, 454) embedded therein.
Next, holes 480 are drilled through the monolithic ceramic substrate 308 to allow access to the second termination portions 316 in step 420.
Finally, lead wires 318 are inserted in the holes 480 and bonded to the second termination portions 316 and a tubular shaft 304 is bonded to the monolithic ceramic substrate 308 by a bonding feature 306 to complete the support pedestal 300 in step 422.
The bonding feature 306 may include a trench, which is filled with an aluminum material to facilitate bonding of the tubular shaft 304 to the plate assembly 302. The bonding feature has been described in a co-pending application assigned to the present Applicant, i.e., U.S. Ser. No. 15/955,431, field Apr. 17, 2018 and titled “Ceramic-Aluminum Assembly with Bonding Trenches,” the content of which is incorporated herein in its entirety for reference.
In this form, no via hole needs to be formed through the ceramic substrate. The resistive heating element 310 is connected to the routing element 312 by the first termination portions in the form of slugs. The routing element may be a metal foil. Therefore, a wide selection of materials are available for forming the routing element and the first termination portions in order to provide good electric conductivity with reduced resistance. By forming a trench to receive the functional material, the resistive heating element can be made very thin to increase the resistance of the resistive heating element.
It should be noted that the disclosure is not limited to the form described and illustrated as examples. A large variety of modifications have been described and more are part of the knowledge of the person skilled in the art. These and further modifications as well as any replacement by technical equivalents may be added to the description and figures, without leaving the scope of the protection of the disclosure and of the present patent.
This application is a continuation-in-part application of U.S. Ser. No. 15/819,028, filed Nov. 21, 2017 and titled “Integrated Heater and Method of Manufacture,” the content of which is incorporated herein in its entirety.
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Number | Date | Country | |
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Child | 15986441 | US |