The present invention relates to a pneumatically operated reciprocating pump that allows, in a simple, reliable, efficient, precise, and inexpensive way, to move fluids, in particular ultrapure fluids, maintaining constant pressure and rate with a positive or negative output offset value close to zero, the pump being mechanically rugged, chemically and universally resistant to etching by acids, solvents and ultrapure fluids such as DI water, and resistant at high temperatures, preferably up to 220° C. The pump is further controlled through a continuous and reliable monitoring, and easily maintainable.
Pneumatically operated reciprocating pumps are very well known in fluid industry. Such pumps usually comprise two pumping chambers, in each one of which a respective flexible bellow slides operating as pumping element, and they are operated by an exchanger that moves pressurized air from one pumping chamber to another when the flexible bellows reach the end of the stroke. The exchanger is provided with an internal spool moving between two positions which alternatively supply the pumping element of a side of the pump with pressurized air simultaneously allowing the other side to expel the air. The movement of the exchanger spool simply alternates the pressurized air and the one to be expelled between the two bellows inside the pump, consequently creating the reciprocating operation of the pump.
U.S. Pat. Nos. 5,558,506, 5,893,707 and US Patent Application No. US 2003/0012668 disclose three of such pneumatically operated reciprocating pumps.
Such pumps are largely used for pumping several types of fluids including water, chemical substances, alimentary substances, and other materials.
However, pneumatically operated reciprocating pumps of the prior art suffer from a number of drawbacks.
First of all, they are often made according to complex designs which hinder disassembly and reassembly of the pump, sometimes making usual maintenance and overhauling operations difficult.
Also, most bellow pumps of the prior art include small metal parts which, in some applications, could be chemically etched. By way of example, when these pumps are used in manufacturing processes in semiconductors factories, they operate in presence of corrosive fluids which chemically etch metals. In order to obviate this problem, some or all the parts which normally get in touch with the fluid (i.e. the wetted parts of the pump) are formed or covered with chemically inert materials, typically of plastic. These pumps often use some metal parts only in external (i.e. not wetted) location, as connections for maintaining the pump body and related pipes assembled with each other, exploiting the fact that the metal is more mechanically resistant and more easily machinable than chemically inert materials. However, also these pumps with only external metal parts, which are normally not in contact with fluids, have manifest problems in application to semiconductor industry. In fact, it is impossible to completely avoid leakages from a pump, whereby small amounts of leaked chemical products unavoidably get in contact with the external metal parts. When this occurs, metal parts corrode and the dissolved corroded particles could dissolve within the pump and contaminate the system. In this case, even small contaminating amounts may be disastrous: failures of chips due to contamination are typically not determined until chips are tested after manufacture is completed. In these circumstances, a single source of metal dissolving in a process fluid may cause a great economical loss, due to both lowering of percentage of operating manufactured chips and long interruption periods of the concerned production line necessary to determine contamination sources and to repair and purify the same production line.
A further drawback from which the pneumatically operated reciprocating pumps of the prior art suffer is due to the difficulty, particularly significant in applications with ultrapure fluids, in controlling and regularizing fluid rate. This problem is due to the same principle of operation of this type of pumps, and in particular to the cyclic movement of pumping membranes or bellows. Irregularity of pulsating flow that is typical of this type of pumps, besides constituting a disturbance factor for the process supported by the pump, may also create drawbacks of contamination in fluids. In order to obviate to such drawback, main manufacturing company allows optional tanks to be connected to the pump circuit which tanks act as shot compensators, which attenuate the irregularity of the delivery fluid rate. However, this regularizing action is not directly related to a measurement of the irregularity of flow and implies adoption of additional external components.
A further drawback is that of managing and controlling pump operation parameters and of monitoring the main components subject to wear. Presently, main manufacturers provide the adoption of optional devices for detecting fluid leakages within the air side, which may indicate flaw or yield of critical components, such as for instance the pumping bellows. In general, use of optical fibers suitably treated for being capable to operate in critical conditions is preferred especially when pumps operate with corrosive fluids. However, such control device are not sufficiently reliable, most of all in case of applications of pumps to semiconductor technology.
Hence, it is an object of the present invention to provide a pneumatically operated reciprocating pump that allows, in a simple, reliable, efficient, precise, and inexpensive way, to regulate rate and pressure of the pump with delivery offset values close to zero.
It is still an object of the present invention to provide such a pump that is easily maintainable, mechanically rugged, and resistant to etching by acids and solvents and to high temperatures.
It is a further object of the present invention to provide such a pump that is controllable through a continuous and reliable monitoring.
It is therefore specific subject matter of this invention a pneumatically operated reciprocating pump comprising two opposed pumping chambers, in each one of which a respective flexible bellow slides between a compressed position and an expanded position, a slide of the two flexible bellows being controlled by shuttle means capable to alternatively let a gaseous fluid in one of the two chambers for expanding the respective flexible bellow, whereby when each one of the two flexible bellows assumes a threshold expanded position it interacts with mechanical means allowing the gaseous fluid to be discharged from the respective chamber, each one of the two flexible bellows having a front end in contact with a shaft that is alternatively pushed by one of the two flexible bellows thus compressing the other, each one of the two chambers being connected to at least one respective suction valve and to at least one respective delivery valve, wherein each delivery valve is provided with compensating elastic means capable to compensate variations of rate of fluid that is pumped by the respective chamber.
Always according to the invention, said compensating elastic means may comprise at least one compensating bellow.
Still according to the invention, each compensating bellow may comprise a plurality of outer coils, separated from each other by a plurality of inner coils, wherein the inner and outer coils have a squared side profile.
Furthermore according to the invention, each delivery valve may be a ball valve.
Always according to the invention, each delivery ball valve may be housed in a respective seat of the pump closed by a tap, each delivery ball valve comprising a case housing a ball, the respective compensating bellow being interposed between the ball and the tap, so that, during pump operation, a front end of the compensating bellow gets in contact with the ball absorbing related impacts and pressure peaks exerted by the fluid pumped by the respective chamber.
Still according to the invention, each suction valve may be a ball valve.
Furthermore according to the invention, each suction ball valve may be housed in a respective seat of the pump closed by a tap, each suction ball valve comprising a case housing a ball and being closed by a cover.
Always according to the invention, the case and the tap of each delivery ball valve and the case and the cover of each suction ball valve may be shaped so as to be provided with three pockets, whereby a corresponding tool provided with three corresponding projections is allowed to insert therein and engage with them.
Still according to the invention, each one of the two flexible bellows may comprise a plurality of outer coils, separated from each other by a plurality of inner coils, wherein the outer and inner coils have a lateral profile that presents concave grooves.
Furthermore according to the invention, said shuttle means may comprise a pneumatically operated shuttle valve comprising a shaped spool sliding between two limit positions within a perforated cylinder, which shuttle valve is connected, for each chamber, to one or more delivery ducts and to one or more ducts for respectively letting and discharging gaseous fluid in and from the respective chamber, the shuttle valve being capable to alternatively open and close the delivery ducts of the two chambers depending on the position of the spool, the spool being moved by the gaseous fluid coming from a chamber through the respective discharge ducts when it is in a position in which it opens the delivery ducts of the other chamber.
Always according to the invention, for each chamber, said one or more delivery ducts and said one or more discharge ducts may be internal to the shuttle valve and to a head covering the respective chamber, the two heads being removably coupled to a pump body, the shuttle valve being fastened to the two heads through hollow screws provided with at least one duct capable to put at least one duct internal to the shuttle valve in communication with at least one duct of the respective head.
Still according to the invention, each one of the two heads and the pump body may be provided with mechanical means for mutual alignment.
Furthermore according to the invention, said mutual alignment mechanical means may comprise, for each head, at least one centering pin insertable in a through hole of the respective head and in a corresponding hole of the pump body.
Always according to the invention, said shuttle means may comprise control electronic means, that controls an electric shuttle connected, for each chamber, to one or more delivery ducts letting gaseous fluid in the respective chamber, the electric shuttle being capable to alternatively open and close the delivery ducts of the two chambers.
Still according to the invention, the electric shuttle may receive the gaseous fluid to alternatively let in the two chambers from a pressure regulator.
Furthermore according to the invention, said control electronic means may comprise at least one timer and a power supply.
Always according to the invention, said control electronic means may further control a pneumatically operated valve, installed on a delivery pipeline of the pump after a flow sensor capable to sense the pressure of the fluid pumped in the delivery pipeline and to send a related sensing signal to said control electronic means.
Still according to the invention, said control electronic means may comprise an electric valve controlling the pneumatically operated valve.
Furthermore according to the invention, the electric shuttle may be a five-way coil electric shuttle a power supply of which is controlled by said control electronic means.
Always according to the invention, the pump may comprise a control electronic unit that receives a signal indicative of the flow of the pumped fluid from a flow sensor mounted on a delivery pipeline of the pump, the control electronic unit controlling an electronic pressure regulator mounted on the compressed air delivery pipeline before said shuttle means depending on a predetermined flow value of the pumped fluid.
Still according to the invention, the control electronic unit may comprise a Programmable Logic Controller or PLC.
Furthermore according to the invention, the control electronic unit may be connected to interface means.
Always according to the invention, said interface means may comprise a display and a keyboard, preferably integrated in a touch-screen display.
Still according to the invention, said predetermined flow value of the pumped fluid may be adjustable.
Furthermore according to the invention, the control electronic unit may be connected, for at least one flexible bellow, to at least one first, preferably optical fiber, sensor internal to the pump capable to provide the control electronic unit with at least one detection signal when said at least one flexible bellow assumes a position within the respective chamber.
Always according to the invention, the control electronic unit may be capable to determine, and preferably to store, a number of cycles performed by the pump of said at least one detection signal.
Still according to the invention, the control electronic unit may be capable to program and signal interventions of preventive maintenance.
Furthermore according to the invention, the control electronic unit may be connected to one or more second, preferably optical fiber, sensors for sensing losses in the gaseous fluid circuit, capable to provide the control electronic unit with at least one signal of detection of presence of pumped fluid.
Always according to the invention, the electronic unit may be connected to one or more third sensors capable to provide the control electronic unit with at least one signal of detection of rate and/or pressure and/or temperature of the pumped fluid.
Still according to the invention, the pump may comprise a removable handle.
Furthermore according to the invention, the pump may be made of a material resistant to corrosion and/or chemical etching, preferably a material comprising one or more materials selected from the group comprising ultrapure thermoplastic materials, organic polymers, and fluoridated polymers, more preferably a material comprising one or more materials selected from the group comprising MFA, TFM, PP, Teflon PFA, pure Teflon, PEEK, PTFE, PVDF, and FEP.
The pump according to the present invention is a reciprocating pump provided with bellows, comprising compensating delivery valves and provided with a system for controlling and monitoring data through a series of sensors, that allows a whole control of the functionalities of the same pump. The compressed air (or the nitrogen) has the function of providing the pneumatically operated shuttle with energy, which shuttle operates the pumping bellows working within two chambers thus causing ultrapure fluids to move.
The bellow reciprocating pump according to the invention, pneumatically or electro-pneumatically controlled, is devoid of metal parts, and it is wholly made of corrosion resistant materials, so that it may be used with acids and corrosive fluids.
Moreover, particular constructive adjustments of the pump components permit to obtain an easily inspectable, mechanically rugged, universally resistant to etching by acids and solvents and at high temperatures, preferably up to 220° C.
According to another aspect of the invention, the pump is controlled by a system for controlling and monitoring data that provides a whole picture of the operation state of the main critical components (suction and delivery valves, bellows, pneumatically operated shuttle), e.g. signaling possible flaw of membranes or bellows due to wear, and it detects during operation the main flow parameters such as rate, pressure, temperature, whole number of the operation cycles. Preferably, such monitoring system comprises a display for displaying information on the pump operation state, on the basis of which the operators may schedule maintenance interventions.
Moreover, according to another aspect of the invention, the pump comprises a pair of compensating valves capable to regulate pump rate and pressure with delivery offset values close to zero, avoiding the use of conventional shot compensators mounted after the pumping system. In this way, the pump is more compact and the circuit after the same is simplified. Also, this allows to avoid the possibility of producing particles which could potentially be generated along the section going from the delivery valves up to the external compensator.
The present invention will be now described, by way of illustration and not by way of limitation, according to its preferred embodiments, by particularly referring to the Figures of the enclosed drawings, in which:
In the Figures, alike elements are indicated by same reference numbers.
The reciprocating motion of the bellows 31 (and 31′) activates pumping a fluid similarly to what disclosed in US Patent No. U.S. Pat. No. 5,893,707, . in respect to which the pump according to the present invention has a simplified assembly system consisting in having made the cylindrical element 33 (and 33′) provided with a respective cap (34′).
The fastening of each one of the pumping bellows 31 and 31′ is carried out through a respective, preferably octagonal, head 2 (and 2′) covering the pump, that is screwed in a gap 101 of the pump body 1 through two threads (not shown in the Figure) present on an inner circular projection 20 (and 20′) of the head 2 (and 2′) engaging corresponding threads, preferably customized with triangular profile, present on the walls of the gap 101. The reciprocating motion of the pumping chambers is carried out thanks to the horizontal slide of a shaft 9 alternatively pushed by a thrust nose of the pumping bellows 31 and 31′ (thrust nose 39′ of the bellow 31′ is visible in
In particular, the reciprocating motion of the pumping bellows 31 (and 31′) is caused by pressurized air (or nitrogen) that is alternatively supplied to the two pumping chambers for pushing the respective bellow 31 (and 31′). During compression phase, movement of bellows 31 and 31′ and plungers 32 and 32′ drags caps 34 and 34′ from their seats (located on the respective pump head 2 or 2′) and it contributes to routing the pressurized air through opening and closing corresponding ducts connected to a shuttle valve 13, assembled outside the pump body 1. A spool 134 slides within the shuttle valve 13 which spool is moved by the air entering the circuit of such ducts starting from the same shuttle valve 13 and returning to the latter leaving the circuit. Depending on its position, the spool 134 alternatively opens and closes the ducts for supplying compressed air in the two pumping chambers.
As it will be illustrated below, the shuttle valve 13 is directly connected to the air supply and discharge ducts of the two pumping chambers so as to form a single body, without external connections or ducts. In particular, the heads 2 and 2′ incorporate some ducts along which compressed air flows from and to the shuttle valve 13.
With reference to
As schematically shown in
The operation of the shuttle valve 13 is now illustrated with reference to FIGS. 1 and 3-6, starting from the position of the spool 134 as shown in
In order to avoid any air loss from the ducts internal to the shuttle valve 13 and to the heads 2 and 2′, assembly of the shuttle valve 13 is carried out after both heads 2 and 2′ have been positioned and centered so as to ensure alignment of the respective ducts.
Making reference to
Making reference to
With reference to
With reference to
An important aspect of the present invention is the use of two compensating bellows 6, interposed between the ball 7 of each delivery valve and the respective tap 5, in order to compensate variations of rate occurring in the pump when motion in the chambers is reversed. Such compensating bellows 6 thus allow a constant delivery rate to be obtained, avoiding the use of conventional shot compensators assembled after the pumping system. This also avoids the possibility of producing particles which could be potentially generated along the section going from the delivery valves up to the external compensator.
With reference to
Still with reference to
With particular reference to
Still with reference to
Such system offers the advantage that the operator's task is reduced to set the desired flow value through the interface unit 202, depending on which the electronic unit 201 automatically controls the electronic regulator 204 for maintaining the air pressure necessary to decrease or increase the pump speed.
The control and monitoring system is also capable to monitor pump operation, in particular detecting the number of operation cycles and any possible break of membranes or bellows due to wear.
In particular, the number of cycles is calculated through suitable optical fiber sensors inserted in correspondence with the accesses of the ducts 24 and 24′ of the head 2 for delivering compressed air in the pumping chambers.
In particular, the number of cycles is detected through suitable optical fibers sensors 205 connected to the electronic unit 201. Such sensors 205 are inserted, for instance, in correspondence with the holes for access to ducts 22 and 22′ (hole 72 of the head 2′ is shown in
Such sensors detects both contact and departure of the bellow 31 or 31′ and, consequently, the related number of shots and/or cycles. In this way, the electronic unit 201 is capable to determine, store and present on the display 202″ data like:
These sensors also carry out a mechanical control allowing to test pump efficiency checking the correct alternate opening and closing of the compressed air ducts. An improper operation of these would affect the movement of the spool 134 of the shuttle valve 13 generating the malfunction of the whole pump.
The pump is further provided with sensors 206 for detecting losses in the compressed air circuit, still connected to the electronic unit 201. Such sensors 206 sense the presence of fluid within the air duct due to a flaw of the bellows 31 and 31′. These sensors 206 are preferably optical fiber ones, and they are inserted within holes made on the cylindrical projection of each one of the heads 2 and 2′ (projection 21′ of the head 2′ is shown in
Other air and/or fluid loss sensors may be installed within the fluid and/or compressed air ducts.
Further sensors may be installed for detecting, during pump operation, main flow parameters, such as rate, pressure, temperature.
All the sensors used in the pump are preferably capable to operate in presence of acids and/or solvents and at temperatures up to 220° C.
In particular, the electronic unit 201 is provided with a software for controlling the pump. The software allows to control pump power up and power down, to execute operations for controlling pump state, to alert in case of detection of failures or malfunctions, and finally it allows to manage maintenance times scheduling pauses for controlling components and for their possible replacement.
The interface unit 202, preferably a touch-screen showing one or more graphical interfaces with which an operator may directly interact, allows configuration and display, in particular, of one or more of the following parameters:
As shown in
Through the selection of the button 304, access is gained to an access managing page, wherein it is possible to choose a level with which entering to operate on the pump. Levels are preferably three: OPERATOR, ENGINEER, and SERVICE. Preferably, for entering each level it is necessary to input a password through a screen graphical keyboard. At each level, the operator is enabled to a different set of functions.
Through the selection of the button 302, access is gained to a pump control graphical interface 305 shown in
Upon each command of pump start, that may be carried out by the operator by selecting the graphical button START, a further window appears on the screen where pump operation parameters may be set and an identifier name may be input which name serves to go back (as time in terms of both hours and date) to all the events and alarms for that type of recipe or process. Upon each stop of the pump, also selectable by the operator in the graphical window opened at the beginning, a file with all related data is closed and, upon the next start, another one is opened.
During pump operation, components are subject to wear in a different manner and hence the pump must be stopped for replacing worn parts. It is important to be capable to provide for a scheduling for carrying out maintenance through a maintenance setting.
Components subject to wear or break are grouped in kit, such as, for instance: a suction valve kit, a delivery valve kit, and a bellow kit. In particular, parameters which have to be monitored for controlling component life time comprise: the type of employed fluid and related temperatures, the number of pumping cycles referred to time, and the pump operating pressure. Each time that the number of cycles or operation hours as set for each kit is reached, page 310 is displayed as shown in
Management of maintenance is carried out on a window related to each kit, which window is accessible by selecting the corresponding icon.
Through the selection of the button 308 of the page 305 access is gained to a graphical interface 313 related to maintenance settings as shown in
Through the selection of the button 309 of the page 305 access is gained to a graphical interface related to detection of pump malfunctions, that displays the machine state. In particular, all the alarms present in the system are displayed with time passed from the event and the alarm state. Through scrolling buttons it is possible to display the whole alarm list and to reset only the alarms which are under restoration condition, while those still persisting remain displayed in the list. The alarm page automatically appears when an alarm occurs.
With reference to
In particular, the controlling system comprises a power supply 152 supplying an electric valve 153 controlling the opening and closing of a pneumatically operated valve 154 installed on the delivery pipeline of the pump 1 (after the outlet mouth of the latter), after a flow sensor, preferably coinciding with the sensor 203 shown in
The heart of the system for controlling the pump 1 is formed by the power supply 152, that is connected to a second timer 157 in turn connected to the five-way coil electric shuttle 151. The electric shuttle 151 is directly connected to the compressed air pneumatic circuit of the pump 1, that controls its reciprocating operation. Regulation of the inlet air pressure is carried out before the electric shuttle 151 through a regulator, preferably coinciding with the electronic regulator 204 shown in
A flow sensor 203 is installed at the outlet mouth 52 of the pump 1, that is capable to emit an alarm signal, monitoring the operation of the pump 1. At the moment when the pneumatically operated valve 154 comes into operation, thus stopping the delivery flow coming from the outlet mouth 52, the sensor 203 senses a pressure increase in the delivery duct of the pump 1 and it automatically disconnects the second timer 157 by opening the related circuit and consequently the system for controlling the pump 1 stops and a both acoustic and visual alarm signal is activated.
A meter 159 for monitoring the effective fluid consumption is installed on the delivery pipeline of the pump 1, after the pneumatically operated valve 154. A touch-screen display 160 permits to display the value detected by the meter 159 that may be reset through the same display 160.
The pump 1 has been developed in order to make the assembling and disassembling operations as simple as possible, e.g. being aided by the use of a single tool for disassembly. In fact, apart from the heads (2 and 2′ of
Also, the high resistance of the connections of the pump makes the latter suitable to be wholly produced in corrosion resistant materials, making it suitable for applications in semiconductor industry.
The pump is preferably made of corrosion resistant materials, such as ultrapure thermoplastic materials and/or organic polymers and/or fluoridated polymers.
No metal part is present in the pump, and the fastening of the components is carried out through threads made on the same parts and no other connecting elements are present, this making the system more reliable. The corrosion resistant materials of the pump comprise one or more materials selected from the group comprising or consisting of MFA, TFM, PP, Teflon PFA, pure Teflon, PEEK, PTFE, PVDF, and FEP.
The present invention has been described, by way of illustration and not by way of limitation, according to its preferred embodiments, but it should be understood that those skilled in the art can make variations and/or changes, without so departing from the related scope of protection.
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Number | Date | Country | |
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20110008188 A1 | Jan 2011 | US |