CH640482A5 - SUCTION BELL SUPPORT. - Google Patents

Description

The invention relates to a suction cup holder according to the preamble of claim 1.

Such supports usually have, in addition to the working opening to be connected to the suction bell, a further connection opening which communicates with the latter and which is to be connected to a vacuum pump. Suction bells are increasingly used today to transport objects with a smooth surface, such as metal sheets and glass sheets, even in smaller companies that do not have vacuum installations at home. You then have to buy separate vacuum pumps and 'lay vacuum lines. In contrast, there is a compressed air installation in practically all companies.

The present invention is therefore intended to further develop a suction cup carrier in accordance with the preamble of claim 1 in such a way that it can be operated using compressed air.

Starting from the prior art mentioned in the preamble of claim 1, this object is achieved according to the invention with the features specified in the characterizing part of claim 1.

Advantageous developments of the invention are specified in dependent claims.

With the development of the invention according to claim 10, a particularly reliable sealing of the venturi channel to the atmosphere is obtained.

With the development of the invention according to claim 11, it is achieved that in order to release the suction cup from the workpiece being carried, not only is the vacuum application ended, but also the suction cup is pressurized, with which particularly rapid release of the workpiece is achieved.

With the development of the invention according to claim 13 it is achieved that the pressure accumulator is automatically filled with compressed air at the same time the venturi channel is started up.

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A carrier according to claim 14 is particularly advantageous because it has only a single valve body, which serves both as a check valve for filling the pressure accumulator and as an automatically operated control valve between the pressure accumulator and the working opening.

With the development of the invention according to claim 15 it is achieved that the valve body together with the valve body can be removed as a unit from the pressure accumulator. This makes assembly and maintenance considerably easier.

The invention is explained in more detail below on the basis of two exemplary embodiments with reference to the accompanying drawing. In this show:

1 shows a longitudinal section through a first suction cup carrier;

Fig. 2 shows a longitudinal section through a second suction cup carrier, in which the suction cup is automatically placed under pressure to release the workpiece being carried.

Fig. 1 shows a suction cup holder with a housing 10, in which a longitudinally extending bore 12 is formed. The end of the bore 12 on the left in the drawing is provided with a thread 14 for connecting a compressed air supply line, and its right end has a thread 16 for connecting an exhaust air hose.

An ejector nozzle body 18, which has an axial channel 20, is inserted into the left end of the bore 12. In the front end wall of the ejector nozzle body 18, a nozzle opening 22 is provided which widens slightly conically outwards.

On the outside, the ejector nozzle body 18 has a cylindrical surface section 24 which is press-fit in the bore 12 and is additionally glued to the wall of the latter. This is followed by a conical surface section 26. The ejector nozzle body 18 is supported with a shoulder 28 on a complementary shoulder of the bore 12.

Similarly, a collector nozzle body 30 is inserted and glued into the bore 12 from the right. It has an axial channel 32, the diameter of which is six times the smallest diameter of the nozzle opening 22. In the left-hand end of the collector nozzle body 30, a truncated cone-shaped recess 34 is provided, in the middle of which a tubular projection molded onto the collector nozzle body 36 is arranged. The end face of the latter ends by a small axial distance in front of the end face of the ejector nozzle body 18, so that a connection to the one through the bore 12, the surface section 26 of the ejector nozzle body 18 and the depression 34 are established via an annular gap 38 of the collector nozzle body 30 is limited space. This space is connected via a radial channel 40 located at the free ends of the two nozzle bodies to a working opening 42 into which a suction cup, not shown in the drawing, is screwed.

Through holes 44 are used to attach the suction cup support to a hoist.

The suction cup holder described above works as follows:

Pressurized air reaches the nozzle opening 22 via the compressed air supply line connected to the thread 14. When the air exits from the nozzle opening 22 and enters the larger diameter channel 32, the air relaxes and its flow rate increases. Similar to a water jet pump, the working opening 42 is thus subjected to negative pressure via the annular gap 38.

Fig. 2 shows a modified suction cup holder, in which the working opening is automatically pressurized when the compressed air is applied to the ejector nozzle body 18.

For this purpose, a cylindrical storage chamber 48 is formed in the enlarged housing 46, which is closed by a cover 50. This engages with a cylindrical projection 52 in the storage chamber 48 and is sealed against it by means of a sealing ring 54. In the cover 50 a channel 56 is formed which is transverse to the axis of the storage chamber 48 and which is closed at one end by a plug 58 and is connected at the other end via a small axial channel section 60 with an axial channel 62 of the housing 15 46. A sealing ring 64 is provided at the joint.

In the lower section of the housing, an ejector nozzle body 18 and a collector nozzle body 30 are arranged in a housing bore 12 in a press fit and glued 20. These parts are 'very similar to those in the suction cup holder according to FIG. 1. Corresponding parts are therefore again provided with the same reference numerals and do not need to be described again here.

25 The thread 14 is, however, provided here in an enlarged diameter head 66 of the nozzle body 18, and the latter additionally has a radial channel 68, which establishes a connection between the channel 20 and the channel 62.

30 A tube 72 is inserted in a fluid-tight manner and has an axial channel 74 in a blind bore 70 of the cover 50 that cuts the channel 56. The latter ends in a larger diameter cylindrical valve chamber 76, which is formed in a molded cup-shaped erud section 78 of the tube 72. The end face of the end section 78 ends at a distance from the bottom 80 of the storage chamber 48, so that the valve chamber 76 is connected to the storage chamber 48 via an annular gap 82.

40 A coaxial projection 84 of the base 80 projects into the valve chamber 76 from below, in which an axial channel 86 is provided, which is connected to the bore 12 at a point which is at the free ends of the two nozzle bodies 18 and 30 lies. 45 Inside the valve chamber 76 is a rotationally symmetrical valve body 88 made of elastomeric material, which has plane-parallel surfaces 90 and 92, which can close the channels 74 and 86, respectively. The valve body 88 also has an integrally formed, umlau-50 fende, conical sealing lip 94, the cross section of which tapers towards the free end. The tip of the cone defined by the sealing lip 94 lies in the channel 74.

A threaded opening 96 is provided in the wall of the storage chamber 48, in which a ventilation plug 98 is arranged, the head of which bears against the outer wall of the housing via a sealing washer 100.

2 works as follows:

In order to pressurize the suction bell connected to the working opening 42, compressed air is again allowed to flow through the channel 20 into the channel 32 with relaxation. The compressed air also reaches the valve chamber 76 via the channels 68, 62, 56 and 74,

there presses the elastic sealing lip 94 radially inward 65 and flows over the annular gap 82 into the storage chamber 48. At the same time the valve body 88 is pressed into a position closing the channel 86, which is further supported by the vacuum built up in the channel 86.

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Once the pressure in the channel 20 has essentially been reached in the storage chamber 48, the sealing lip 94 rests against the wall of the valve chamber 76 and now prevents a return flow of compressed air from the storage chamber 48 into the channel 74 in the manner of a check valve. The valve body 88 remains in the position closing the channel 86 due to the differential pressure application (including the vacuum application on the circular section of the underside covering the channel 86). These conditions, under which the working opening 42 is continuously subjected to negative pressure, remain unchanged as long as pressure is provided via the compressed air supply line. A pressure of approximately 8 atmospheres then typically prevails in the storage chamber 48.

If the compressed air supply to the channel 20 is interrupted, the top of the valve body 88 is no longer pressurized. By pressurizing the outer annular portion of the valve body 88 from the storage chamber 88, the valve body 88 is quickly pushed upward, and the pressurized air in the storage chamber 48 quickly flows through the channel 86 io and the working opening 42 to the suction bell. This is therefore quickly subjected to excess pressure and immediately detaches from the workpiece.

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1 sheet of drawings

Claims (21)

640482 1. Suction cup support with a housing which has a working opening under vacuum for connection to a suction cup, characterized in that the working opening (42) opens transversely into a venturi channel (22, 32) pressurized with compressed air. 2. Carrier according to claim 1, characterized in that the venturi channel is formed by an ejector nozzle (22) and a collector nozzle (32) aligned with it and arranged at an axial distance. 2nd PATENT CLAIMS 3. Carrier according to claim 2, characterized in that the smallest cross section of the ejector nozzle (22) is approximately equal to one sixth of the cross section of the collector nozzle (32). 4. Carrier according to claim 2 or 3, characterized in that the ejector nozzle (22) extends conically as seen in the direction of flow. 5. Carrier according to one of claims 2 to 4, characterized in that the collector nozzle body (30) in the end face facing the ejector nozzle (22) has a truncated cone-shaped recess (34), in the center of which a cylindrical collecting tube (36) is arranged. 6. Carrier according to claim 5, characterized in that the opening angle 'of the frustoconical recess (34) is approximately 120 °. 7. Carrier according to one of claims 2 to 6, characterized in that the ejector nozzle body (18) tapers conically towards the nozzle opening and that this ejector nozzle body (18) is located in a cylindrical housing bore (12). 8. A carrier according to claim 7, characterized in that the opening angle of the ejector nozzle body (18) is about 20 °. 9. Carrier according to one of claims 1 to 8, characterized in that the working opening (42) communicates with an annular gap (38) delimited by the end faces of the ejector nozzle body (18) and collector nozzle body (30). 10. Carrier according to one of claims 1 to 9, characterized in that the ejector nozzle body (18) and / or the collector nozzle body (30) is pressed and / or glued into a housing bore (12). 11. Carrier according to one of claims 1 to 10, characterized in that the working opening (42) via a servo valve (76, 88) can be connected to a pressure accumulator (48), which at the same time when the compressed air supply to the venturi channel (22 , 32) is switched to the open position. 12. Carrier according to claim 11, characterized in that the pressure accumulator (48) is connected via a check valve (94) to the compressed air supply line (20) to the venturi channel (22, 32). 13. Carrier according to claim 12, characterized in that the check valve (94) is formed by a flexible skirt of a valve body (88). 14. Carrier according to claim 13, characterized in that the valve body (88) is the valve body of the servo valve and in the closed position on its one side with the entire cross section is acted upon by the pressure in the compressed air supply line (20) while it is on its opposite side is pressurized in a small central section with the pressure in the working opening (42) and on an annular outer section with the pressure in the pressure accumulator (48). 15. Carrier according to claim 14, characterized in that the valve body (88) is arranged in a substantially cylindrical valve chamber (76), in the one end wall of which a connecting line (74) to the compressed air supply line (20) opens, and the opposite end wall (80 ) delimits an annular passage (82) to the pressure accumulator (48) and contains a channel (86) which communicates with the working opening (42). 16. Carrier according to claim 15, characterized in that the apron of the valve body (88) forming a check valve (94) is designed as a conical sealing lip that diverges towards the second end wall (80) of the valve chamber. 17. Carrier according to claim 16, characterized in that the cross section of the sealing lip decreases towards its free end. 18. Carrier according to one of claims 15 to 17, characterized in that the cup-shaped valve chamber (48) is carried by a tube (72) which is provided by a cover (50) for the pressure accumulator integrated in the housing (46) of the carrier (48) is worn. 19. Carrier according to claim 18, characterized in that the cover (50) has a sealing (54) in the pressure chamber (48) inserted cylindrical projection (52). 20. Carrier according to claim 18 or 19, characterized in that the tube (72) via a transverse channel (56) of the cover (50) and an axial channel (62) of the housing with the compressed air supply line (20) is connected. 21. Carrier according to one of claims 1 to 20, characterized in that the volume of the pressure accumulator (48) is greater than the effective volume of a suction bell to be connected to the working opening (42).