NL1016948C2 - Peristaltic pump has housing, in which is channel containing flexible hose with suction and pressure sides and drive body for moving fluid material in hose from suction side to pressure side - Google Patents

Abstract

The peristaltic pump (1) has a housing (3), in which is a channel containing a flexible hose (4) with suction (5) and pressure sides (6) and a drive body (8) for moving fluid material in the hose from the suction side to the pressure side. Outside the housing extends a tubular connecting piece (11,12) which with its outer periphery locates over a part of its length on the suction side against an inner periphery of the flexible hose. A pressure ring with its inner periphery over at least a part of the length of the connecting piece locates against a part of the outer periphery of the flexible hose to press the hose inner periphery against the outer periphery of the tubular connecting piece. The connecting piece on its side close to the pressure side is provided with an all-round outer end with an outermost flank and an innermost flank. The outermost flank forms an inwardly directed angle between 0 and 15 degrees with the center line of the connecting piece.

Description

Short indication: Peristaltic pump with a housing.

The invention relates to a peristaltic pump provided with a housing, a channel arranged in the housing, a flexible hose arranged in the channel with a suction side and a pressure side, a displacement body for expelling a liquid matter from the suction side to the pressure side in the hose, a tubular connecting piece extending beyond the housing and abutting with its outer circumference over a part of its length on the suction side against the inner circumference of the flexible hose and a pressure ring which with its inner circumference over at least a part of the length of the connecting piece abuts at least a part of the outer circumference of the flexible hose for pressing the inner circumference of the flexible hose against the outer circumference of the tubular connecting piece.

Peristaltic pumps, also called hose pumps, have been used industrially for many years for pumping liquids, in particular those with a higher viscosity and many solid abrasive parts, such as, for example, mortar in building projects. In the most common embodiment, the flexible hose, which is often thick-walled and reinforced, lies on the inside of an arcuate pressure surface. On the inside of the arcuately bent hose there is a rotating body with a number of, for example two or three, rollers or shoes which push the liquid into the hose during rotation. During the described rotation, the hose is continuously loaded on an alternating tensile load. Specifically for applications in food technology, this entails the risk that gaps arise where contaminants that are not or only very difficult to remove accumulate. This problem arises in particular where the flexible hose is coupled to tubular connection pieces for coupling the peristaltic pump with external pipes such as pipes or hoses.

A peristaltic pump has been on the market for several years now under the brand name Verderf! Ex. With this pump, a tubular connector protrudes into the end of the hose on the suction side. A pressure ring presses the hose, which is made of an elastic rubber, with its inner circumference against the outer circumference of the tubular connecting piece. For inserting the tubular connecting piece into the end of the flexible hose during mounting of the peristallic pump, the tubular connecting piece is provided on the pressure side with a locating edge with in longitudinal section a point shape with two converging flanks which point is a top angle of approximately 60 °. It has now been found that such a configuration does not entirely preclude contamination 5 from accumulating between the flexible hose and the tubular connecting piece.

It is an object of the invention to provide a peristaltic pump that is even more suitable for applications in food technology due to a reduced risk of contaminants accumulating within the pump. To this end, the peristaltic pump 10 according to the invention is characterized in that the tubular connector on the pressure-side side is provided with a circumferential end with an outer flank and an inner flank, the outer flank forming an inward-facing angle with the center line of the tubular connector located between 0 and 15 °. It may be clear that at an angle of 0 ° the outer flank is parallel to the center line. Although the use of such an outer flank makes assembly of the tubular connecting piece in the flexible hose more difficult, the risk of contamination accumulating in a space between the tubular connecting piece and the flexible hose is considerably reduced if not excluded. Said risk is in particular extremely small if the outer flank is parallel to the center line of the tubular connecting piece.

The hygienic properties of the pump are further improved if the tubular connecting piece extends on the pressure side of the pressure ring over a distance between 0 and 12 mm outside the pressure ring in the direction of the pressure side. Because of the compression of the elastic material of the flexible hose, in such a configuration an inward boiling will occur just beyond the tubular connecting piece so that an even better seal is obtained between the tubular connecting piece and the flexible hose. Despite the varying tensile load on the flexible hose, no gap will arise between the coupling piece and the hose. Preferably said extension distance is between 0.5 and 5.0 mm and even more preferably it is between 1.0 and 3.0 mm. If the distance is too great, there is a risk that the described boiling is insufficiently able to prevent the formation of a gap between the flexible hose and the tubular connecting piece. If the distance is too small, on the other hand, there is a risk that the boiling will become too large, so that a shadow effect will occur behind the boiling on the pressure side, as a result of which material can accumulate on site, which is also undesirable from a hygienic point of view.

According to a preferred embodiment, the inner flank makes an outwardly directed angle with the center line of the tubular connecting piece between 0 and 45 °. Such an inclined inner flank allows the connecting piece to seamlessly connect to the hose. As a result, the flow of the liquid material at the location of the transition between the coupling piece and the hose is disturbed as little as possible. Also, by using such an inner flank, an annular end on the pressure side of the tubular coupling piece can be obtained with a limited thickness.

To prevent cracking in the flexible hose, the outer flank and the inner flank are connected to each other by an annular surface with a thickness between 0.5 and 1.5 mm. Smaller thicknesses could give rise to cracking in the hose. With larger thicknesses, there is a risk that a boiling or bulging as described earlier during the changing tensile load of the hose does not remain abut against the annular surface, as a result of which contaminants can accumulate in the resulting gap.

A very advantageous embodiment of the invention is obtained if the pressure ring is interrupted and resilient. Because of the interruption, it is possible to reduce the diameter of the pressure ring while simultaneously pressing against the outer circumference of the flexible hose.

Good pressure over the entire circumference of the flexible hose is obtained if the pressure ring encloses at least 345 ° of the circumference of the flexible hose in the pressed state of the flexible hose. With such a small opening angle of a maximum of 15 °, there will be little room for the flexible hose to bulge out between the free ends of the interrupted spring beyond the pressure ring. Good pressure on the flexible hose is thus obtained.

If the free, facing ends of the interrupted pressure ring have flanks facing the center line, the confining effect of the material of the flexible hose through the pressure ring is increased.

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The pressure ring is preferably provided on the pressure side with a beveled surface for conductive cooperation with a beveled surface arranged in the housing. A movement of the pressure ring in the direction of the axis of the tubular connecting piece will at the same time result in an inward radial movement of the pressure ring, whereby clamping occurs between the pressure ring and the flexible hose.

It is also advantageous if the pressure ring on the suction side is provided with a beveled surface for conductive cooperation with a beveled surface arranged in a closing flange. By arranging the closing flange, the pressure ring is shifted in the direction parallel to the center line and because of the effectiveness of the said chamfered surfaces, the pressure ring will also move towards the center line. If chamfered surfaces are provided on the pressure ring both on the suction side and on the pressure side, this causes a parallel position of the pressure ring on the center line.

According to a very advantageous embodiment, the closing flange is arranged around and attached to the tubular connecting piece. As a result of this attachment, the mutual position of the closing flange and the tubular connecting piece is a constant given between which during assembly no separate adjustment is necessary. A source of assembly errors is thus avoided.

The invention will be further elucidated on the basis of the description of a preferred embodiment with reference to the following figures.

Figure 1 shows a partially cut-away peristaltic pump.

Figure 2 shows the components of the peristaltic pump on the suction side in exploded view and in section.

Figure 3 shows Figure 2 in the assembled state.

Figure 4 shows the part surrounded by a circle in more detail in Figure 3.

Figure 5 shows a pressure ring.

Figure 6 shows a perspective view of Figure 3 for the sake of clarity in partially cut-away condition.

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Figure 1 shows a peristaltic pump 1 with a partial cover plate 2. The pump comprises a housing 3 through which a flexible hose 4 extends from a suction side 5 to a pressure side 6. The hose extends semicircularly inside the housing against a semicircular pressure surface 7 of the housing 3. On the inside of the hose 4 there is a rotor 8 which rests with its outside 9 on the inside of the hose 4. Two outward facing shoes 10 are attached to the circumference of the rotor 8, of which, incidentally, one hides behind cover plate 2. The shoes 10 deform hose 10 During operation of the peristaltic pump, rotor 8 rotates clockwise with liquid substance in hose 4 being pushed on the one hand by a shoe, on the other being sucked in due to the vacuum that the shoe in the part of the hose just passed. In this way, liquid material is moved from the suction side 5 to the pressure side 6.

For fixing the ends of the hose 4 with the surroundings of the peristaltic pump 1, tubular coupling pieces 11, 12 are provided. On the basis of the following figures, it will be further explained how the tubular coupling piece 11 is connected to the suction side of the hose 4.

Figure 2 shows in exploded view the various parts which are located on the suction side of the hose 4. Hose 4 extends on the suction side with some play through a part 13 of the housing surrounding the hose 3. This surrounding part 13 is at its end provided with an annular recess 14 for receiving a pressure ring 15 and a part of closing flange 16. This is clearly shown in particular in figures 3 and 6. The closing flange 16 surrounds and is welded to the coupling piece 11. Pressure ring 15 is interrupted as shown in figure 5, so that two free ends 17, 18 are formed which are spaced apart by X in the unloaded state. Pressure ring 15 is made of a resilient steel which makes it possible to reduce the diameter of the pressure ring and at the same time distance X under the influence of an inward radial force in a loaded state. The pressure ring 15 is located around a part of the end of hose 4. For reasons still to be explained, the pressure ring 15 is in a loaded pressed condition, whereby the outer diameter of the hose 4 is smaller, as a result of which 1 016948 6 immediately after coupling piece 11 the hose 4 protrudes internally according to protrusion 19.

For radially loading the pressure ring 15 externally inwardly radially, it is provided on both the suction side and the pressure side with beveled sides 20, 21. The surrounding part 13 and the closing flange 16 are also provided with a beveled side 22, 23 on their inner sides. conductive cooperation with chamfered sides 21, 20 of pressure ring 15. By attaching sealing flange 16 to the housing 3 by means of the four fixing bolts 24, each of which is tightened with a moment of approximately 50 Nm 10 for obtaining a controlled clamping and which is Drilling holes (not further shown) in closing flange 16 extend into bores in the housing 3 provided with internal screw thread, the beveled sides 22 and 21 on the one hand and 20 and 23 on the other come into conductive cooperation. Thanks to this conductive cooperation 15, pressure ring 15 will assume a smaller diameter, as a result of which a clamping of the outside of the hose 4 will occur. For an improved clamping, pressure ring 15 is provided on its inside with four grooves 25.

The pressure side end 26 of coupling piece 11 has an outwardly directed inner flank 27 and an outer flank 29 parallel to the axis 28. The inner flank 27 and the outer flank 29 are connected to each other via a blunt end 26 annular surface 30 with a radial thickness of 1.0 mm. Because of this blunting surface 30, the risk is excluded that the end 26 will initiate cracking in hose 4.

In operation, the flexible hose 4 will be continuously loaded on an alternating tensile load. Protuberance 19 will continuously deform under the influence of this varying tensile load, but these deformations are such that the annular surface 30 remains covered by protuberance 19. Hereby it can be guaranteed that, despite the varying tensile load, no gap will arise between the tubular coupling piece 11 and the protrusion 19 of hose 4. Consequently, the risk is excluded that a gap is created between coupling piece 11 and hose 4 in which contaminants can accumulate. A hygienic design of the peristaltic pump at the location of the connection between coupling piece 11 and hose 4 is therefore guaranteed.

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Claims (13)

1. Peristaltic pump provided with a housing, a channel arranged in the housing, a flexible hose arranged in the channel with a suction side and a pressure side, a displacement body for expelling a liquid matter in the hose from the suction side to the pressure side, a tubular connecting piece extending beyond the housing and abutting with its outer circumference over a part of its length on the suction side against the inner circumference of the flexible rod and a pressure ring which abuts with its inner circumference over at least a part of the length of the connecting piece at least a part of the outer circumference of the flexible hose for pressing the inner circumference of the flexible hose against the outer circumference of the tubular connecting piece, characterized in that the tubular connecting piece is provided with a circular end on the side facing the pressure side with an outer flank and an inner flank, with the outer flank flank makes an inward-facing angle with the center line of the tubular connector located between 0 and 15 degrees. 2. Peristaltic pump according to claim 1, characterized in that the outer flank is parallel to the axis of the tubular connecting piece. 3. Peristaltic pump according to claim 1 or 2, characterized in that the tubular connecting piece extends on the pressure side of the pressure ring over a distance between 0 and 12 mm outside the pressure ring in the direction of the pressure side. A peristaltic pump according to claim 3, characterized in that the tubular connecting piece extends on the pressure side of the pressure ring over a distance between 0.5 and 5.0 mm outside the pressure ring in the direction of the pressure side. 5. Peristaltic pump according to claim 4, characterized in that the tubular connecting piece extends on the pressure side of the pressure ring over a distance between 1.0 and 3.0 mm outside the pressure ring in the direction of the pressure side. 6. A peristaltic pump according to any one of the preceding claims, characterized in that the inner flank forms an outwardly directed angle with the center line of the tubular connecting piece between 0 and 45 degrees. 1016943 A peristaltic pump according to any one of the preceding claims, characterized in that the outer flank and the inner flank are connected to each other by an annular surface with a thickness between 0.5 and 1.5 mm. A peristaltic pump according to any one of the preceding claims, characterized in that the pressure ring is interrupted and resilient. 9. Peristaltic pump according to claim 8, characterized in that the pressure ring encloses at least 345 degrees of the circumference of the flexible hose in the pressed-in state of the flexible hose. 10. Peristaltic pump according to claim 8 or 9, characterized in that the free ends of the interrupted pressure ring have flanks facing the center line. Peristaltic pump according to one of claims 8 to 10, characterized in that the pressure ring is provided on the pressure side with a chamfered surface for conductive cooperation with a chamfered surface arranged in the housing. 12. Peristaltic pump according to any one of claims 8-11, characterized in that the pressure ring on the suction side is provided with a beveled surface for conductive cooperation with a beveled surface arranged in a closing flange. A peristaltic pump according to claim 12, characterized in that the closing flange is arranged around and is attached to the tubular connecting piece. 4% f; .4 Η I O <^ ^ W