Patent Description:
Atomic Layer Epitaxy (ALE) method was invented by Dr. Tuomo Suntola in the early <NUM>'s. Another generic name for the method is Atomic Layer Deposition (ALD) and it is nowadays used instead of ALE. ALD is a special chemical deposition method based on the sequential introduction of at least two reactive precursor species to at least one substrate. Thin films grown by ALD are dense, pinhole free and have uniform thickness. For example, in an experiment aluminum oxide has been grown by thermal ALD from trimethylaluminum (CH<NUM>)<NUM>Al, also referred to as TMA, and water resulting in only about <NUM>% non-uniformity over a substrate wafer.

One interesting application of ALD technique is providing protective coatings on surfaces. <CIT> discloses providing a protective coating for an ALD or CVD reaction chamber.

According to a first example aspect of the invention there is provided a method for protecting a target pump interior, the method comprising:.

The sequential self-saturating surface reactions (according to ALD) produce the desired protective coating within the pump interior. Accordingly, the target pump interior may be coated by using ALD so that all surfaces within the target pump which see the reactive gases end up coated. The target pump may be running during the whole coating process.

In certain example embodiments, the reactive gases and inactive purge gas enter the target pump interior via the inlet manifold. In certain example embodiments, reaction residue and purge gas exit the target pump interior via the exhaust manifold.

The target pump interior may be used as the reaction chamber for ALD reactions. The desired process temperature for ALD reactions may be obtained simply by keeping the target pump running. Additional heating may not be needed. Accordingly, in certain example embodiments, the method comprises providing a required processing temperature by keeping the target pump running without using other heating means.

In certain example embodiments, the inlet manifold comprises ALD reactor in-feed equipment. In certain example embodiments, the in-feed equipment comprises in-feed line(s) and at least the desired precursor and inactive gas flow controlling elements, such as valve(s), mass flow controller(s) or similar, and their control system.

The control system may be implemented for example by software in a laptop computer or similar. Accordingly, in certain example embodiments, the inlet manifold comprises one or more in-feed lines with their controlling elements controlled by a computer-implemented control system. Suitable replaceable precursor and inactive gas sources may be attached to the in-feed equipment.

In certain example embodiments, the exhaust manifold comprises a vacuum pump. In certain example embodiments, the method comprises pumping reaction residue and purge gas from the target pump interior by a vacuum pump attached to the exhaust manifold. The vacuum pump may provide one or more of the following effects: It may be configured to pump reaction residue from the target pump interior via the target pump outlet. It may be used to pump the target pump interior into vacuum.

In certain example embodiments, the target pump is a vacuum pump. In certain example embodiments, the sequential self-saturating surface reactions are performed within a temperature range extending from ambient temperature to <NUM>, i.e., the ALD processing temperature is within this range. In certain example embodiments, the ALD processing temperature is within the range of <NUM> - <NUM>. In certain example embodiments, the processing temperature is achieved by running the target pump itself. In certain other example embodiments, the target pump is instead or additionally heated before and/or during ALD processing by a separate heater.

In certain example embodiments, as mentioned in the foregoing, the type of the target pump is a vacuum pump. In other embodiments, the target pump is of another type. In yet other embodiments, the term pump is construed broadly covering also compressors, the interior of which is coated by the disclosed method.

In certain example embodiments, the method comprises forming a flow channel via target pumps placed in a row, and providing simultaneous protection of the interiors of the target pumps by using the flow channel. In certain example embodiments, the method comprises forming the flow channel by attaching the exhaust manifold of a previous pump to a pump inlet of the following pump in the row.

Herein is also described an apparatus for protecting a target pump interior, comprising:.

Accordingly, the apparatus, when being used, in certain example embodiments is configured to expose the target pump interior to sequential self-saturating surface reactions by sequential inlet of reactive gases via the inlet manifold into the target pump interior and outlet of reaction residue via the exhaust manifold (while the target pump is kept running or kept off).

In certain example embodiments, the inlet manifold comprises precursor vapor and purge gas in-feed lines and their controlling elements.

In certain example embodiments, the exhaust manifold comprises a vacuum pump.

In certain example embodiments, the apparatus is mobile. The protecting apparatus comprising the inlet manifold and the exhaust manifold may be mobile so that it can be moved to meet the user's needs. In certain example embodiments, the inlet manifold and exhaust manifold are separate devices designed to work together in a target pump interior protecting method. In certain example embodiments, the inlet manifold comprises a target pump-specific attachment part to attach to target pump inlet. Accordingly, in certain example embodiments, the inlet manifold comprises a target pump-specific attachment part configured to attach the inlet manifold into the target pump inlet. In certain example embodiments, the exhaust manifold comprises a target pump-specific attachment part to attach to target pump outlet.

Herein is also described a method for protecting a target pump interior, the method comprising:.

The target pump not running means the target pump being "off". In certain example embodiments, the sequential self-saturating surface reactions are performed at ambient temperature. In certain other example embodiments, the sequential self-saturating surface reactions are performed at an elevated temperature (i.e., temperature higher than the ambient temperature). In certain example embodiments, the sequential self-saturating surface reactions are performed within a temperature range extending from ambient temperature to <NUM>. In certain example embodiments, the target pump is heated before and/or during ALD processing by a separate heater. The embodiments described in connection with the first aspect and their combinations apply also to the third aspect, and vice versa.

The above embodiments are used merely to explain selected aspects or steps that may be utilized in implementations of the present invention. Any appropriate combinations of the embodiments may be formed.

In the following description, Atomic Layer Deposition (ALD) technology is used as an example. The basics of an ALD growth mechanism are known to a skilled person. As mentioned in the introductory portion of this patent application, ALD is a special chemical deposition method based on the sequential introduction of at least two reactive precursor species to at least one substrate. The at least one substrate is exposed to temporally separated precursor pulses in the reaction chamber to deposit material on the substrate surfaces by sequential self-saturating surface reactions. In the context of this application, the term ALD comprises all applicable ALD based techniques and any equivalent or closely related technologies, such as, for example MLD (Molecular Layer Deposition) technique.

A basic ALD deposition cycle consists of four sequential steps: pulse A, purge A, pulse B and purge B. Pulse A consists of a first precursor vapor and pulse B of another precursor vapor. Inactive gas and a vacuum pump are typically used for purging gaseous reaction by-products and the residual reactant molecules from the reaction space during purge A and purge B. A deposition sequence comprises at least one deposition cycle. Deposition cycles are repeated until the deposition sequence has produced a thin film or coating of desired thickness. Deposition cycles can also be more complex. For example, the cycles can include three or more reactant vapor pulses separated by purging steps. All these deposition cycles form a timed deposition sequence that is controlled by a logic unit or a microprocessor.

In certain example embodiments as described in the following, there is provided a method and apparatus for protecting a pump's (hereinafter referred to as target pump) interior with a protective coating. The target pump itself forms a reaction chamber, and there is no separate substrate, but the surfaces of the target pump interior form a substrate (substrate here meaning the material on which a process is conducted). All these surfaces can be coated by an ALD process in which precursor vapors are sequentially inlet via an inlet manifold into the target pump interior. The reaction residue is outlet from the target pump interior via an exhaust manifold. The target pump is kept running during the deposition process. The desired process temperature for ALD reactions within the target pump may be obtained simply by keeping the target pump running. In other embodiments, the target pump is "off". In all embodiments, the target pump can be optionally heated before and/or during ALD processing by a heater.

<FIG> shows the method and related apparatus in certain example embodiments. The apparatus used to protect the interior of a target pump <NUM> comprises an inlet manifold <NUM> and an exhaust manifold <NUM>. The apparatus may be a mobile apparatus. A mobile apparatus may be conveniently moved into the proximity of pumps to be protected, if needed.

The inlet manifold <NUM> is configured to be attached to the target pump inlet <NUM>. <FIG> shows the inlet manifold <NUM> attached by a first attachment part <NUM> to the target pump inlet <NUM>. The first attachment part <NUM> may be a target pump-specific part. The exhaust manifold <NUM> is configured to be attached to the target pump outlet <NUM>. <FIG> shows the exhaust manifold <NUM> attached by a second attachment part <NUM> to the target pump outlet <NUM>. The second attachment part <NUM> may be a target pump-specific part.

The inlet manifold <NUM> comprises ALD reactor in-feed equipment <NUM>. The in-feed equipment <NUM> comprises the required in-feed lines and their controlling elements. Attached to the first attachment part <NUM> in <FIG> is a first precursor vapor in-feed line <NUM>, a second precursor in-feed line <NUM> and a purge gas in-feed line <NUM>. The first precursor in-feed line <NUM> originates from a first precursor source <NUM>, the second precursor in-feed line <NUM> from a second precursor source <NUM>, and the purge gas in-feed line <NUM> from a purge/inactive gas source <NUM>.

The in-feed line controlling elements comprise flow and timing controlling elements. A first precursor in-feed valve <NUM> and mass flow controller <NUM> in the first precursor in-feed line <NUM> control the timing and flow of first precursor pulses. Correspondingly, a second precursor in-feed valve <NUM> and mass flow controller <NUM> in the second precursor in-feed line <NUM> control the timing and flow of second precursor pulses. Finally, a purge gas in-feed valve <NUM> and mass flow controller <NUM> control the timing and flow of purge gas.

In the embodiment shown in <FIG>, the operation of the in-feed equipment <NUM> is controlled by a control system. <FIG> shows a control connection <NUM> between the in-feed equipment <NUM> and a control system <NUM>. The control system <NUM> may be implemented for example by software in a laptop computer or similar.

In certain example embodiments, the ALD process within the target pump interior is performed in a vacuum. The exhaust manifold <NUM> optionally comprises a vacuum pump <NUM>. In certain example embodiments, the vacuum pump <NUM> is located in the end of an exhaust line <NUM> which is attached into the target pump outlet <NUM>. The vacuum pump <NUM> can be optionally controlled by the control system <NUM> via an optional electrical connection <NUM> (which is between the control system <NUM> and the vacuum pump <NUM>). Depending on the type of the target pump, the vacuum pump <NUM> pumps the whole interior of the target pump <NUM> or at least a part of it into vacuum. The target pump <NUM> can comprise different pressure regions. In <FIG>, the volumes <NUM> and <NUM> depict such regions. The arrow <NUM> depicts the flow direction within the target pump <NUM>, that is, from target pump inlet <NUM> via the target pump interior (via volume <NUM> and then <NUM>, if applicable) to the target pump outlet <NUM>. If the target pump <NUM>, too, is a vacuum pump, the volume <NUM> in <FIG> may be considered as a vacuum pressure region and the volume <NUM> as an ambient pressure region of the target pump <NUM>. When the target (vacuum) pump <NUM> is running, the volume <NUM> stays in vacuum. The exhaust line vacuum pump <NUM> is then used to pump also the volume <NUM> into a vacuum.

Further referring to <FIG>, it should be noted that in other embodiments, the inlet manifold and exhaust manifold <NUM> may be arranged differently. Instead of separate in-feed lines at least part of the in-feed lines may be in common. The valve types may vary. The flow controlling element locations may vary, etc. For example, three-way valves may be used instead of two-way valves, immediately reflecting changes in in-feed line routing. Concerning the precursor sources and purge gas, their selection depends on the implementation and desired coating. The target pump can be heated by an optional heater <NUM>. The operation of the heater can be optionally controlled be the control system <NUM> over a connection.

Applicable pump materials are, for example, metals, such as steel and aluminum, but the materials are not limited to these materials. Applicable coatings are, for example, metal oxides, such as aluminum oxide, titanium oxide, tantalum oxide, and tungsten carbide, and their combinations, but the coatings are not limited to these materials. Applicable ALD processing temperatures are ambient temperature - <NUM> in certain example embodiments, although other ranges are also applicable. In certain example embodiments, the type of the target pump is a vacuum pump. In other embodiments, the target pump is of another type. In yet other embodiments, the term pump is construed broadly covering also compressors, the interior of which is coated by the disclosed method.

<FIG> shows method steps in accordance with what has been disclosed in <FIG>. First, a mobile pump protecting apparatus is carried next to the target pump <NUM> to be protected, or the target pump <NUM> is moved next to the either mobile or fixed pump protecting apparatus. The inlet manifold <NUM> is attached to target pump inlet <NUM> (step <NUM>) and the exhaust manifold <NUM> to target pump outlet <NUM> (step <NUM>). The target pump <NUM> is optionally turned on (step <NUM>). The target pump interior is exposed to sequential introduction of precursor vapors, separated by purge steps, in accordance with ALD. The reaction residue and purge gas is pumped into the vacuum pump <NUM> (step <NUM>). In the deposition process, a conformal protective coating is obtained. The pump is turned off (step <NUM>), and the inlet manifold <NUM> is detached from target pump inlet <NUM> (step <NUM>) and the exhaust manifold <NUM> from target pump outlet <NUM> (step <NUM>).

In further example embodiments, there is provided pump chain for protecting the pump interiors of the pumps forming the chain. In these embodiments, the inlet manifold is attached to a first target pump inlet similarly as shown in the previous embodiments. A first end of a first exhaust manifold is attached to the first target pump outlet and the opposite end of the exhaust manifold to a second target pump inlet. A first end of a second exhaust manifold is attached to the second target pump outlet and the opposite end to a third target pump inlet, and so on. By this arrangement, a plurality of pumps arranged in a chain can be protected simultaneously by one ALD processing. The gases enter the first target pump interior via the inlet manifold, and the further target pump interiors via the exhaust manifold of the previous pump, until they end up into a vacuum pump placed in the end of the chain. Accordingly, a flow channel is formed via target pumps placed in a row, and simultaneous protection of the interiors of the target pumps is provided by using the flow channel. The target pumps can be vacuum pumps, themselves, or any other applicable pumps.

Without limiting the scope and interpretation of the patent claims, certain technical effects of one or more of the example embodiments disclosed herein are listed in the following: A technical effect is protecting pump interior by a conformal protective coating. Another technical effect is protecting a ready-made (assembled) pump including its sealing surfaces. If the protection would be performed separately for each pump part before assembly, this would make the parts vulnerable to scratches during assembly. Another technical effect is using the target pump itself to provide heating of the target pump interior, by keeping the target pump running during the deposition process.

It should be noted the some of the functions or method steps discussed in the preceding may be performed in a different order and/or concurrently with each other. Furthermore, one or more of the above-described functions or method steps may be optional or may be combined.

The foregoing description has provided by way of non-limiting examples of particular implementations and embodiments of the invention a full and informative description of the best mode presently contemplated by the inventors for carrying out the invention. It is however clear to a person skilled in the art that the invention is not restricted to details of the embodiments presented above, but that it can be implemented in other embodiments using equivalent means without deviating from the characteristics of the invention.

Claim 1:
A method for protecting a target pump interior, comprising:
providing a target pump inlet (<NUM>) with an inlet manifold (<NUM>) and a target pump outlet (<NUM>) with an exhaust line (<NUM>) by attaching (<NUM>) the inlet manifold (<NUM>) to the target pump inlet (<NUM>) and attaching (<NUM>) the exhaust line (<NUM>) to the target pump outlet (<NUM>) the target pump itself thus forming a reaction chamber;
coating the target pump interior by exposing the target pump interior to sequential self-saturating surface reactions by sequential inlet of reactive gases via the inlet manifold (<NUM>) into the target pump interior and outlet of reaction residue via the exhaust line (<NUM>), while the target pump is kept running;
detaching (<NUM>) the inlet manifold (<NUM>) from the target pump inlet (<NUM>) and detaching (<NUM>) the exhaust line (<NUM>) from the target pump outlet (<NUM>); and wherein
the inlet manifold (<NUM>) comprises one or more in-feed lines (<NUM>, <NUM>, <NUM>) with their controlling elements (<NUM>, <NUM>, <NUM>, <NUM>, <NUM>, <NUM>) controlled by a computer-implemented control system (<NUM>),
characterized by providing a required processing temperature by keeping the target pump running without using other heating means.