BR112017000494B1 - VENTURI DEVICE AND SYSTEM COMPRISING A VENTURI DEVICE - Google Patents

Abstract

VENTURI DEVICE AND SYSTEM COMPRISING A VENTURI DEVICE. Venturi devices and systems incorporating them are described. Venturi devices include a lower body defining a passage having a movement section and a discharge section spaced a distance apart to define a first Venturi opening and a second Venturi opening downstream of the first Venturi opening in a position that divides the discharge section into a first portion between the first and second Venturi openings and a second portion leading beyond the second Venturi opening and, including an upper body defining a suction passage in fluid communication with the first and second venturi openings. Venturi openings. The movement section and the discharge section converge at the first Venturi opening.

Description

Technical field

[001] This application relates to the creation of a vacuum by means of a Venturi device and, more particularly, to a Venturi device that has two Venturi openings. In the example embodiments described herein, the Venturi device is connected to a high pressure source (a pressure greater than atmospheric pressure) as its source of motion and is referred to as an ejector.

State of the art

[002] In some vehicles, vacuum is used to operate or assist in the operation of various devices. For example, vacuum can be used to help a driver apply the vehicle's brakes, operate the turbocharger, purge fuel vapor, actuate the heating and ventilation system, and actuate the transmission component ( driveline). If the vehicle does not produce vacuum naturally, such as from the intake manifold, consequently a separate vacuum source is required to operate such devices. While a vacuum or ejector can produce a vacuum when fed with either boost or manifold vacuum, the depth of the vacuum produced will be a function of the pressure difference between the pressure applied to the motion port and the pressure applied to the discharge port. However, on supercharged engines where intake manifold pressures are often pressures greater than atmospheric pressure, intake manifold vacuum can be replaced or increased with vacuum from an ejector. An ejector, as used here, is a diverging and converging nozzle assembly connected to a pressure source above atmospheric pressure. By passing pressurized air through the ejector, a low pressure region can be created within the ejector so that air can be drawn from a vacuum reservoir or can act directly on a device requiring vacuum, thus reducing the pressure inside the vacuum reservoir or device that requires vacuum.

[003] Typical ejectors cannot produce a suction pressure below atmospheric pressure when the driving pressure exceeds 192 kPa absolute, and maximum vacuum is produced with a driving pressure of less than 135 kPa absolute. However, supercharged engines routinely operate above 135 kPa absolute, so there is a need to improve the performance of an ejector in such a vehicle. These conventional ejectors are limited in the vacuum they can produce, in part because different boost pressures cause the location of the minimum pressure to move to different locations within the ejector. Specifically, as the driving pressure increases beyond a given value relative to the discharge pressure, the point of minimum vacuum creation moves progressively below the discharge passage.

[004] Examples of known devices are disclosed in documents US 2008/121480, US 4759691 and US 2011/186151.

[005] What is needed is an ejector that can produce vacuum over a range of driving pressures.

Synthesis

[006] In one aspect, Venturi devices are described that produce vacuum at a range of driving pressures through suction suction (aspiration) at multiple locations along the discharge section. The Venturi devices include a lower body defining a passage having a driving section and a discharge section spaced a distance apart from each other to define a first Venturi opening and, which converges on the first Venturi opening and, which features a second Venturi opening downstream of the first Venturi opening in a position that divides the discharge section into a first portion between the first and second Venturi openings and a second portion leading beyond the second Venturi opening. Venturi devices also include an upper body that defines a suction passage in fluid communication with the first and second Venturi openings. In one embodiment, the first Venturi opening and the second Venturi opening have a center-to-center distance of about 12 mm to about 50 mm.

[007] In one embodiment, the first Venturi opening is generally wider at a higher point, when viewed in a longitudinal cross-section, than at a generally central point. In another embodiment, the first Venturi opening is generally wider at an upper point and at a lower point, when viewed in a longitudinal cross-section, than at a point generally central between the upper point and the lower point. In this embodiment, the lower body defines a first connector that surrounds the lower point of the Venturi opening and has a first cover tightly connected to the first connector.

[008] In one embodiment, the lower body and the upper body together define a first gate valve chamber in fluid communication with the first Venturi opening, the first gate valve chamber comprising a plurality of fingers which extend upwardly away from the first Venturi opening in a spaced annular arrangement, thus defining a seat for a sealing element. The upper body defines one or more openings in the first chamber of the gate valve and the first Venturi opening is displaced downstream of the one or more openings. In this embodiment, the plurality of fingers decreases in height the closer they are to the first Venturi opening.

[009] In another embodiment, the lower body and the upper body together define a second chamber of the gate valve in fluid communication with the second Venturi opening, the second chamber of the gate valve comprising a plurality of fingers which extend upwardly away from the second Venturi opening in a spaced annular arrangement, thus defining a seat for a sealing element. The upper body defines one or more openings in the second chamber of the gate valve and the second Venturi opening is displaced upstream of the one or more openings. In this embodiment, the plurality of fingers decreases in height the closer they are to the second Venturi opening.

[0010] In another aspect, systems are described that include any of the Venturi devices described herein. The Venturi device is arranged in the system with a source of moving fluid connected to its driving section and a first device that requires vacuum connected to its suction inlet.

Brief description of the drawings

- figure 1 is a side plan view of an embodiment of a multi-Venturi device. - figure 2 is a plan view, in longitudinal cross-section, of the multi-Venturi device of figure 1. - figure 3 is an exploded plan view of a second embodiment of a multi-Venturi device. - figure 4 is a plan view, in the assembled longitudinal cross-section, of the multi-Venturi device of figure 3. - figure 5 is an enlarged view of the first Venturi opening of figure 4. - figure 6 is a view in perspective, from above, inside the lower body of the multi-Venturi device in figure 3.

Detailed Description

[0011] The following detailed description will illustrate the general principles of the invention, examples of which are further illustrated in the accompanying drawings. In the drawings, like reference numbers indicate identical or functionally similar elements.

[0012] As used herein, “fluid” means any liquid, suspension, colloid, gas, plasma or combinations thereof.

[0013] In Figure 1, a multi-Venturi ejector 100 is illustrated that includes a lower body 106 and an upper body portion 108 that, when assembled together, define a first gate valve 114 aligned with a first Venturi opening 112 in the lower body 106 and a second gate valve 118 aligned with a second Venturi opening 116 in the lower body 106. The first and second gate valves 114, 118 may be constructed or have features similar to those described in the patent applications thereof. holder No. 14/600,598, filed on January 2015 and No. 14/509,612, filed on October 8, 2014, which are incorporated herein in their entirety by reference.

[0014] Referring now to figures 1 and 2, the lower body 106 defines a duct 122 that includes a first Venturi opening 112 that separates the duct 122 into a converging section 124 and a diverging section 126 that define internal passages that taper gradually, continually narrowing as they approach the first Venturi opening 112 and create a Venturi effect in the high pressure fluid as it passes from the converging section 124 to the diverging section 126. The lower body 106 also includes a second Venturi opening 116, which is downstream of the first Venturi opening 112 in a position that separates the divergent section 126 into a first portion 130 that is located between the first and second Venturi openings 112, 116 and includes the inlet discharge port 134 (figure 2) and, in a second portion 132, which leads beyond the second Venturi opening 116 to the discharge outlet 136 (figure 2) defined by the discharge port 142. The converging section 124 includes a movement 140 which defines a movement input 127, which may be connected to a pressure source that is greater than atmospheric pressure, and includes a movement outlet 128 at the first Venturi opening 112. The discharge port 142 is capable of be connected to a lower pressure source 103 relative to the source connected to the motion port 140.

[0015] As illustrated in figure 2, the upper body 108 defines a suction port 144 that presents a suction passage 146 and defines one or more first openings 148 therein, in fluid communication with the first gate valve 114 and the first Venturi opening 112 and, one or more second openings 149 therein, in fluid communication with the second gate valve 118 and the second Venturi opening 116. Consequently, as high pressure fluid flows from a pressure source larger 101 through the first Venturi opening 112, suction is created to draw a flow of fluid from the suction port 144 to the first Venturi opening 112 and, as the high pressure fluid and suction flow passes through the second opening of Venturi 116, additional suction is created to draw a flow of fluid from the suction port 144 through the second Venturi opening 116. The suction port 144 may be connected to a device that requires the vacuum 102 to operate the device. or, it may be connected to a vacuum reservoir, which is considered here to be a device that requires vacuum.

[0016] The first and second gate valves 114, 118 are constructed to prevent fluid from flowing from the lower body 106 of the multi-Venturi ejector 100 through the suction port 144 to the device requiring vacuum or the reservoir. vacuum. Gate valves 114, 118 are preferably formed by coupling the lower body 106 with the upper body 108. To accomplish this, the lower body includes valve seats 162a, 162b which are respectively defined by a continuous outer wall 164a , 164b. An orifice 168a, 168b is defined in each valve seat 162a, 162b to permit airflow communication with respective Venturi openings 112, 116. Each valve seat 162a, 162b may include a plurality of radially spaced fingers 170 that extend upwardly from a surface (away from the Venturi opening) to support a sealing member 172.

[0017] The upper body 108 includes valve seats 174a, 174b defined by continuous outer walls in a similar manner to that described above in relation to valve seats 162a, 162b. Each of the valve seats 174a, 174b may include a pin 176a, 176b that extends downward toward the associated Venturi opening 112, 116. The pins 176a, 176b function as a guide for translation of the sealing elements 172 within the gate valves 114, 118. Accordingly, each sealing member 172 includes a hole therethrough sized and positioned to receive the pin 176a, 176b within the respective gate valve 114, 118.

[0018] The second Venturi opening 116 may be shaped and sized in the same manner as the first Venturi opening 112 or may be substantially the same. The first Venturi opening 112 and the second Venturi opening 116 have a center-to-center distance in the range of about 12 mm to about 50 mm, more preferably, in the range of about 15 mm to about 30 mm.

[0019] The Venturi device of figures 1 and 2 features a first Venturi opening 112 and a second Venturi opening 116 that are generally wider at a higher point, when viewed in the longitudinal cross-section of figure 2, than at a generally central point.

[0020] As illustrated in figure 2, the second Venturi opening 116 can be moved upstream either from a generally central point of the one or more second openings 149 in the upper body 108 or from a plane coincident with a transverse axis B through , generally, from the center of the second gate valve 118.

[0021] Referring now to the embodiment of figures 3 to 6, a multi-Venturi device 200 is illustrated which includes a lower body 206 and an upper body 208 which, when assembled together, define a first aligned gate valve 214 with a first Venturi opening 212 in the lower body 206 and a second gate valve 218 aligned with a second Venturi opening 216 in the lower body 206. The lower body 206 defines a duct 222 that includes a first Venturi opening 212 that separates the duct 222 into a converging section 224 and a diverging section 226 that define internal passages, which taper gradually and continuously, narrowing as they approach the first Venturi opening 212 and create a Venturi effect in the fluid as they passes from the converging section 224 to the diverging section 226. The lower body 206 also includes a second Venturi opening 216 that lies downstream of the first Venturi opening 212 in a position that separates the diverging section 226 into a first portion 230 that lies between the first and second Venturi openings 212, 216 and includes the discharge inlet 234 (figure 4) and in a second portion 232 leading beyond the second Venturi opening 216 to the discharge outlet 236 (figure 4) defined by discharge port 242. The converging section 224 includes a motion port 240 that defines a motion inlet 227, which is capable of being connected to a pressure source, and includes a motion outlet 228 at the first Venturi opening 212 The discharge port 242 is capable of being connected to a lower pressure source compared to the source connected to the movement port 240.

[0022] As illustrated in figure 4, the upper body 208 defines a suction port 244 having a suction passage 246 and defining one or more first openings 248 therein in fluid communication with the first gate valve 214 and the first opening Venturi valve 212 and one or more second openings 249 therein in fluid communication with the second gate valve 218 and the second Venturi opening 216. Consequently, as fluid flows through the first Venturi opening 212, suction is created. to draw a flow of fluid from the suction port 244 to the first Venturi opening 212 and, as the fluid and suction flow pass through the second Venturi opening 216, additional suction is created to draw a flow of fluid from from the suction port 244 through the second Venturi opening 216. The suction port 244 may be connected to a device that requires vacuum to operate the device or may be connected to a vacuum reservoir. As illustrated, the first Venturi opening 212 may be moved O1 from a generally central point of the one or more first openings 148 in a downstream direction toward the second Venturi opening 216, and the second Venturi opening 216 may be moved upstream. O2 from a generally central point of the one or more second openings 249 in the upper body 208 or from a plane coincident with a transverse axis through, generally, for both Venturi openings, the center of the respective gate valve.

[0023] The second Venturi opening 216 may be shaped and sized in the same way as the first Venturi opening 212 or may be substantially the same. The first Venturi opening 212 and the second Venturi opening 216 have a center-to-center distance Dc-c in the range of about 12 mm to about 50 mm, more preferably, in the range of about 15 mm to about 30 mm.

[0024] The first and second gate valves 214, 218 are constructed to prevent fluid from flowing from the lower body 206 of the multi-Venturi ejector 200 through the suction port 244 to the device requiring vacuum or the vacuum reservoir . Gate valves 214, 218 are preferably formed by coupling the lower body 206 with the upper body 208. To accomplish this, the lower body includes valve seats 262a, 262b which are respectively defined by a continuous outer wall 264a , 264b. An orifice 268a, 268b is defined in each valve seat 262a, 262b to allow airflow communication with respective Venturi openings 212, 216.

[0025] The upper body 208 includes valve seats 274a, 274b defined by continuous outer walls in a similar manner to that described above in relation to valve seats 262a, 262b. Each of the valve seats 274a, 274b may include a pin 276a, 276b that extends downward toward the associated Venturi opening 212, 216. Pins 276a, 276b function as a guide for translation of sealing elements 172 within gate valves 214, 218. Accordingly, each sealing element 172 includes a hole therethrough sized and positioned to receive pin 276a, 276b within their respective gate valve 214, 218.

[0026] As illustrated in the enlarged view in figure 5, any of the Venturi openings described herein, with particular reference to the first Venturi opening 212 in figure 4, is generally wider at an upper point 233 and at a lower point 235, when viewed in a longitudinal cross-section, than at a generally central point 237 aligned with the central longitudinal axis C between the upper point 233 and the lower point 235. The width of the Venturi opening 212 tapers symmetrically from a maximum width W1 at the upper and lower ends, respectively, of the opening to a minimum width W2 at the center point 237. As a result, the free area defined by the Venturi opening 212 is symmetrical with respect to a plane dividing the duct 222 into upper and lower halves 257, 259 (in the illustrated embodiment, above and below the C axis), thereby improving flow conditions and decreasing turbulence and resulting noise as fluid flows through Venturi opening 212 when compared to suction systems which incorporate Venturi openings with asymmetrical configurations (e.g. conical or tapered).

[0027] With reference to figures 4 and 5, the lower body 206 defines a first chamber 280 that surrounds the movement outlet end 229 of the converging (motion) section 224, surrounds the discharge inlet end 231 of the divergent section 226 (discharge) and, includes or begins with orifice 268a. With the motion outlet end 229 and the discharge inlet end 231 extending into the first chamber 280, flow is provided around the entire outer surface of both. The lower body 206 further defines a first connector 286 (figure 3) that surrounds the lower point 235 (figure 5) of the first Venturi opening 212 and further comprises a first lid 292 tightly connected to the first connector 286, thus helping to define the first chamber 280. The first connector 286 may be an annular flange that projects outwardly from the lower body 206, but is not limited thereto. The lower body 206 also defines a second chamber 281 for the second Venturi opening 218. The second chamber 281 surrounds the two opposing ends 290 of the discharge section formed by forming the second Venturi opening 216. The two opposing ends 290 extend toward inside the second chamber 281 such that flow is provided around the entire outer surface of both. Here also the lower body 206 further defines a second connector 288 which may be an annular flange projecting outwardly from the lower body 206, surrounding a lower point of the second Venturi opening 216. A second cover 294 is leaktightly connected to the second connector 288, thus helping to define the second chamber 281.

[0028] The described structure, incorporating flow to both the first Venturi opening 212 and the second Venturi opening 216 from above and below the Venturi openings, as well as on all sides thereof, provides a flow rate improved suction flow for a given motive flow and discharge pressure when compared to a system that incorporates fewer flow directions into the Venturi opening due to the described system providing greater ability to utilize the Venturi effect created by the motive flow through duct 222 5, arrows 253 and 255 indicate the flow path through the upper and lower points 233, 235 of the Venturi opening 212. The Venturi forces generated by the motive flow through the upper half 257 of the duct 222 through the Venturi opening 212 produces suction primarily along the flow path 253 through orifice 268a. Venturi forces generated by the driving flow through the lower half 259 of the duct 222 through the Venturi opening 212 produce suction primarily along the flow path 255.

[0029] Referring to Figures 3-4 and 6, the lower body 206 further defines a first plurality of fingers 302 that extend upwardly away from the first Venturi opening 212 toward the upper body 208 for inclusion within of the first gate valve 214 and a second plurality of fingers 304 extending upwardly away from the second Venturi opening 216 toward the upper body 208 for inclusion within the second gate valve 218. The first plurality of fingers 302 and the second plurality of fingers 304 separately define a seat for a sealing member 172. Both the first and second plurality of fingers 302, 304 may be arranged in an annular configuration with the fingers spaced circumferentially apart from each other. . The plurality of fingers may be equidistant from each other, with the exception of the pair of third fingers 314, which may be further apart from each other due to their proximity to one of the holes 268a, 268b.

[0030] The holes 268a, 268b may have an irregular shape, may be generally circular in cross-section or may include a portion that is generally circular in cross-section. As illustrated in Figure 6, each of the holes 268a, 268b includes a trough portion 322 and a portion that is generally circular in cross section 324. As illustrated in the example embodiment, each of the first and second plurality of fingers 302, 304 may include discrete fingers that decrease in height the closer the particular discrete finger is to its respective Venturi opening 212, 216. For example, the first finger 310 has the greatest height H1, measured from a coincident plane with an inner bottom surface 306 of the respective gate valve unit 214, 218 and, circumferentially, is furthest from the Venturi opening. The second fingers 312 are shorter than the first finger 310 and have a height of H2. The third fingers 314 are shorter than the second fingers 312 and have a height of H3. The height H2 of the second fingers 312 can be from about 70% to about 90% of the total height of the first finger 310 and the third fingers can be from about 70% to about 90% of the height of the second fingers 312. With This type of support structure defining a seat for the sealing element 172, the sealing element 172 may deflect enough to allow a high diversion of fluid flow from the vacuum-requiring device 102 when the pressure in the vacuum-requiring device vacuum 102 is greater than a fluid pressure coupled to discharge port 224 and also provides rapid and more uniform closing of each of the gate valves. Although three discrete finger heights are illustrated, more fingers may be used to define the seat for the sealing member 172 and thus appropriate heights may be introduced so that the total height decreases as the fingers are positioned closer together. of the Venturi opening. In the embodiment of Figures 3-6, referring to one of the sets of the plurality of fingers as an example, the first finger 310 is the tallest, the second fingers 312 are about 1 mm shorter than the first finger and, the third fingers are about 2 mm shorter than the first finger (about 1 mm shorter than the second fingers).

[0031] In both embodiments described in the figures, the sealing elements 172 can be reinforced to improve performance. The sealing element 172 has a generally central reinforcing element 173, as shown in Figure 4. The sealing elements 172 have a generally central hole that receives the pin 176a, 176b or 276a, 276b, respectively, but is not limited thereto. . In another embodiment (not illustrated), one or more guides may be positioned around the periphery of the sealing member and the sealing member may or may not include flutes that receive the guides. The reinforcing member 173 may be at least partially overmolded by a sealing material, or enclosed within a sealing material. The reinforcing element 173 enables the sealing elements 172 to resist extrusion between the plurality of closely spaced fingers 170 (Figure 2) and 302, 304 (Figure 3-4) when experiencing a large change in pressure. In one embodiment, the reinforcing member 173 is of, or includes, metal, having a rigidity that enables the sealing member 172 to support extrusion between the fingers as explained previously. As used herein, the term “metal” is used generically to represent all materials that may be pure metal, metallic alloys, metallic compounds and combinations thereof, presenting adequate rigidity. In another embodiment, the reinforcing element 173 may be carbon fiber or plastics such as nylon or acetyl with or without filler (typically 30% by volume) such as glass, mineral and the like. Additional details of exemplary embodiments of the reinforced sealing elements can be found in the United States patent application, from the same owner, No. 14/600,598, filed on January 20, 2015.

[0032] An advantage of the multi-Venturi ejector is that the ejector can produce a usable vacuum over a wider range of flow pressures (e.g., boost pressures) compared to ejectors that feature only a single Venturi opening.

[0033] In one embodiment, the multi-Venturi ejector may include a noise attenuation unit (not illustrated) that is the same, or similar, to the unit described in patent application No. US 61/913,756, filed in December 9, 2013, incorporated here in its entirety.

Claims (17)

1. Venturi device (100, 200), comprising: - a lower body (106, 206) defining a passage having a driving section (124, 224) and a discharge section (126, 226) spaced at a distance of one on the other to define a first Venturi opening (112, 212), the driving section (124, 224) and both discharge sections (126, 226) define continuously, gradually tapering internal passages which narrow as they approach of the first Venturi opening (112, 212) and, presenting a second Venturi opening (116, 216) downstream of the first Venturi opening (112, 212) at a position that divides the divergent section from the discharge section (126, 226) in a first divergent portion (130, 230) between the first and second Venturi openings (112 and 116, 212 and 216) and a second divergent portion (132, 232) leading beyond the second Venturi opening (116, 216); - an upper body (108, 208) defining a suction passage in fluid communication with both the first and second Venturi openings (112 and 116, 212 and 216); - a first gate valve (114, 214) defined by the lower body (106, 206) and the upper body (108, 208) and housing the sealing element (172), the first gate valve (114, 214) controlling the flow of fluid through the first Venturi opening (112, 212); and - a second gate valve (118, 218) defined by the lower body (106, 206) and the upper body (108, 208) and housing the sealing element (172), the second gate valve (118) controlling the fluid flow through the second Venturi opening (116, 216); ; wherein when fluid flows through the first Venturi opening (112, 212), a suction is created to direct the flow of fluid from the suction passage (146, 246) to the first Venturi opening (112, 212), and When both the fluid flow and the suction flow pass through the second Venturi opening (116, 216), additional suction is created to extract a fluid flow from the suction passage through the second Venturi opening (116, 216) ; said Venturi device (100, 200) being characterized in that the upper body (108, 208) defines one or more openings (149, 249) in the second chamber of the gate valve (118, 218) and the second Venturi opening (116 , 216) is displaced (Or, O2) upstream from a generally central point of the one or more openings (149, 249) toward the first Venturi opening. 2. Venturi device (100, 200), according to claim 1, characterized in that the first Venturi opening (112, 212) and the second Venturi opening (116, 216) have a distance between centers of 12 mm at 50mm. 3. Venturi device (100, 200), according to claim 1, characterized in that the first Venturi opening (112, 212) is wider at a higher point (233), when viewed in a longitudinal cross-section, than than at a central point (237). 4. Venturi device (100, 200), according to claim 1, characterized in that the first Venturi opening is wider at an upper point (233) and a lower point (235), when viewed in a longitudinal cross-section , than at a central point (237) between the upper point (233) and the lower point (235), thus the first Venturi opening (112) has a width that tapers symmetrically from a maximum width (W1) at the point upper (233) and lower point (235) of the first Venturi opening (112) to a minimum width (W2) at the central point (237). 5. Venturi device (100, 200), according to claim 4, characterized in that the lower body (106, 206) defines a first connector (286) that surrounds the lower point (235) of the first Venturi opening (112 , 212) and further comprises a first cover (292) tightly connected to the first connector (286). 6. Venturi device (100, 200), according to claim 1, characterized in that the lower body (106, 206) and the upper body (108, 208) together define a first gate valve chamber ( 114, 214) of the first gate valve in fluid communication with the first Venturi opening (112, 212), the first chamber of the gate valve (114, 214) comprising a plurality of fingers (302) extending upwardly, away from the first Venturi opening (112, 212) in a spaced annular arrangement, thus defining a seat for a sealing element (172). 7. Venturi device (100, 200), according to claim 6, characterized in that the upper body (108, 208) defines one or more openings (148) in the first chamber of the gate valve (114, 214) and the first Venturi opening (112, 212) is displaced, downstream of the one or more openings (148). 8. Venturi device (100, 200), according to claim 7, characterized in that the plurality of fingers (302) decrease in height the closer they are to the first Venturi opening (112, 212). 9. Venturi device (100, 200), according to claim 1, characterized in that the lower body (106, 206) and the upper body (108, 208) together define a second gate valve chamber ( 118, 218) of the second gate valve in fluid communication with the second Venturi opening (116, 2016), the second chamber of the gate valve (118, 218) comprising a plurality of fingers (304) extending upwardly, away from the second Venturi opening (116, 216) in a spaced annular arrangement, thus defining a seat for a sealing element (172). 10. Venturi device (100, 200), according to claim 8, characterized in that the plurality of fingers (304) decreases in height the closer it is to the second Venturi opening (116, 216). 11. System comprising a Venturi device (100, 200) as defined in claim 1, characterized by comprising: - a lower body (106, 206) defining a passage having a driving section (124, 224) and a discharge section (126, 226) spaced at a distance from each other to define a first Venturi opening (112, 212), the driving section (124, 224) and both discharge sections (126, 226) define continuously, internal passages that gradually taper which narrows as they approach the first Venturi opening (112, 212) and, presenting a second Venturi opening (116, 216) downstream of the first Venturi opening (112, 212) in a position that divides the diverging section of the discharge section (126, 226) into a first diverging portion (130, 230) between the first and second Venturi openings (112 and 116, 212 and 216) and a second diverging portion (132, 232) leading beyond Venturi's second opening (116, 216); and - an upper body (108, 208) defining a suction passage in fluid communication with both the first and second Venturi openings (112, 212 and 116, 216); whereby when high pressure fluid flows through the first Venturi opening (112, 212), a suction is created to direct the flow of fluid from the suction passage (146) to the first Venturi opening (112, 212), and as the high pressure fluid and suction flow both pass through the second Venturi opening (116, 216) additional suction is created to draw a flow of fluid from the suction passage (146) through the second Venturi opening ( 116, 216); - a driving flow source (101) fluidly connected to the driving section (124, 224) of the Venturi device; and - a first vacuum requiring device (102) connected to the suction inlet (144, 244) of the Venturi device. 12. System, according to claim 11, characterized in that the first Venturi opening (112, 212) and the second Venturi opening (116, 216) have a center-to-center distance (Dc-c) of 12 mm to 50mm. 13. System according to claim 11, characterized in that the lower body (106, 206) and the upper body (108, 208) together define a first gate valve chamber (114, 214) of the first valve valve in fluid communication with the first Venturi opening (112, 212), the first chamber of the gate valve (114, 214) comprising a plurality of fingers extending upwardly away from the first Venturi opening (112, 212) in a spaced annular arrangement, thereby defining a seat for a sealing element (172). 14. System according to claim 13, characterized in that the upper body (108, 208) defines one or more openings (148) in the first chamber of the gate valve (114, 214) and the first Venturi opening (112, 212) is displaced downstream of the one or more openings (148). 15. System, according to claim 14, characterized in that the plurality of fingers (302) decrease in height the closer they are to the first Venturi opening (112, 212). 16. System according to claim 11, characterized in that the lower body (106, 206) and the upper body (108, 208) together define a second gate valve chamber (118, 218) of the second valve valve in fluid communication with the second Venturi opening (116, 216), the second chamber of the gate valve (118, 218) comprising a plurality of fingers (304) extending upwardly away from the second Venturi opening (116 , 216) in a spaced annular arrangement, thereby defining a seat for a sealing element (172). 17. System, according to claim 16, characterized in that the plurality of fingers (304) decrease in height the closer they are to the first Venturi opening (112, 212).