FI89833B - Two-part metal clamp connection - Google Patents

Description

'11 1 Two-piece metal clamp Tudelad metallisk klämförbindning 5

The invention relates to a two-part metal clamping connector for pipes and hoses made of polymeric material, provided with a connecting piece formed as a pipe sleeve with an insertion area with circumferential ribs which can be inserted at the end of the pipe. over.

DE-PS 36 08 843 discloses a method for producing a tightening connection Ί5 for pipes and hoses made of polymeric material. According to this method, a connecting piece formed as a cylindrical tubular sleeve is placed at the end of a pipe or hose from a plug-in area ribbed on its outer circumference. The cylindrical push-in sleeve, which is axially displaceable relative to the pipe axis, is then pressed to provide a tightening connection 2q over the pipe or hose end from the inserted push-in area. It is apparent from the prior art that the end of a pipe or hose expands before the injection area is placed on its outer circumference. In this case, in addition to the compressive force produced by the push-in sleeve, the shrinkage force 25 of the expanded polymeric material is further used to hold the pipe or hose end in the injection area.

DD-PS 128 216 further discloses another method of forming a tightening joint for pipes and hoses formed of polymeric materials. In this method, the injection site is driven using a force 2Q to the unexpanded end of the pipe or hose.

This pushing is facilitated by sharpening the pipe sleeve at its open end and rounding or chamfering the circumferential ribs at least in the compression direction.

The circumferential ribs of this prior art have the same height as the unlined joint of the injection area. The grooves between the circumferential ribs: 35 S Q Λ 7. '2 ^ are considered to be flattened and so wide that the polymer tube can bend due to its inherent elasticity when the injection area is compressed before the next circumferential rib enters the bottom of the groove.

5 After pressing in the injection area, the push-in sleeve is pressed over the end of the pipe or hose in the opposite direction to the pressing direction of the injection area. Since the push sleeve is formed smaller in inner circumference than the outer circumference of the hose or pipe end from the pressed injection area, after filling the grooves of the pipe sleeve, the excess material moves in the direction of the free end of the hose or pipe end when the push sleeve is pressed over. This excess material moves with it before the free end of the pusher sleeve to its end stop and remains as a circulating oversized material after the pusher sleeve has reached its end stop.

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Due to the tolerances between the polymeric pipe or hose end and the metal parts, this phenomenon can in the negative case result in the pipe and hose wall material being squeezed out of a certain vector region of the metal injection area when the push-in sleeve is pushed out 20, but not in the opposite vector. only to a small extent. Since these compression joints are generally used when individual elements have to be joined with large tolerances, this detrimental phenomenon is particularly common in the prior art.

This is not only an optical disadvantage, but such differences in the material in the compression areas form adhesion surfaces to external influences which can adversely affect the tightness of the compression joint to be produced.

The object of the invention is to avoid the negative effects of the prior art and to provide a push-sleeve connection for pipes and hoses made of polymeric materials in the form of a two-part metal clamp-35 connector, which offers a flawless connection in terms of both optical effects and technical structure.

3 b 9 8 3 3 1 According to the invention, it is proposed that the rib turned towards the flange stop extends above its above ribs and is formed on its outer side facing the ribs in response to the end face of the pushed tube and that this high rib with inner flange, g outer circumferential wall, flange the free end form a receiving chamber for the pressed wall material in connection with the pressing of the push sleeve.

The advantage of this structure is considered to be that the receiving chamber formed in the flange response is completely closed to the outside. The optical advantage of this is that the unevenly compressed pipe or hose wall material does not appear outwards with larger tolerances, but is taken into the tolerance size in a more or less receiving chamber. The primary function of this receiving chamber is thus to receive the pipe or hose wall material displaced by the compression of the push-in sleeve according to the selected tolerances.

Another advantage is that the end of the installation is clearly determined, since the push-in sleeve is pressed up to the flange stop. In addition, the molding work of the extruded material is reduced because the material advances into the receiving chamber according to the invention. The force required to press the pusher sleeve on is produced to a predictable amount, which is very relevant to the construction and installation of the pressing tool 25. In addition, the tolerance range of the wall thicknesses of the machined pipes can be extended by the measures according to the invention.

According to the invention, the volume of the receiving chamber can be influenced so that the high rib has an inner side delimiting the receiving chamber from the side of the injection area together with the inner side of the flange abutment and the outer circumferential wall of the injection area therebetween. In this case, the receiving chamber is enlarged by a groove in the injection area circumferentially inside it. Its receiving volume can be adjusted in this range by a high rib distance from the inner flange of the flange response.

4 b 9 8 3 6 1 In another embodiment, the high rib is connected to the inner side of the flange abutment with its outer circumferential surface parallel to the axis of the injection area.

This application can be used when smaller tolerances are used in the pipes or hoses to be connected, because the volume of the receiving chamber 5 is then formed without the groove of the injection area only from the outer circumference of the high rib and the inner circumference of the push-in sleeve together with the inner sides of the flange stop.

The drawing schematically shows exemplary embodiments of a tightening-1Q connector according to the invention as follows:

Figure 1 shows the injection area and the pulled-on, sleeved pipe end.

Ί5 Fig. 1a shows the injection area of Fig. 1 and a partially extruded push-in sleeve.

Figure Ib shows the injection area of Figure 1 and the fully extruded push-in sleeve.

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Fig. 2 shows the injection area of Fig. 1, in which the high rib is formed in another way.

Figure 2a shows the injection area of Figure 2 and the partially extruded push sleeve 25.

Figure 2b shows the injection area of Figure 2 and the fully extruded push sleeve.

Figure 1 shows the injection area 11 and the inserted tube or hose 2. Before the injection, the tube or hose 2 is expanded from the outer circumference of the injection region 11 so that the drawing can take place without the use of greater forces.

35 The sleeved area of the tube or hose 2 is guided over the ribs 12,13,14,15 when pushed and is located on the outer side of the high rib 16 in its lower area. The grooves 121,131, li 5 b 9 8 3 3 1 141,151 between the ribs 12,13,14,15,16 start in this presentation from the sleeved area of the pipe or hose 2. With its height H, the high rib 16 considerably exceeds the height of the ribs 12,13,14,15 so that it can act as a circumferential response to the end face 21 of the sleeve pushed over the pipe or hose 2.

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The inner side 162 of the high rib 16 and the inner side 111 of the flange stop 110 and the outer circumferential wall 113 of the insertion area 11 between them form the lower part of the receiving chamber 3 in this presentation.

Ί0 In Fig. 1a, the push-in sleeve 4 is partially pressed over the sleeved part of the pipe or hose 2. The grooves 121,131 between the ribs 12,13,14 are filled by this compression with the wall material of the pipe or hose 2. It can be clearly seen from this presentation that the accumulation of the wall material 21 of the hose or pipe 2 protrudes in the direction of the inner side 111 of the flange stop 110 in the region of the free end 41 of the push sleeve 4.

Fig. 1b shows the insertion area 11 of Fig. 1 and the fully compressed push-in sleeve 4. The free end 41 of the push-in sleeve 4 is then in pressure-20 contact with the inner side 111 of the flange abutment 110. The circumferential wall 113 of the free end 41 a receiving chamber 3 for the accumulation of wall material 21 of the hose or pipe 2 is then formed between the inner sides 162.

The metal tightening joint 1 according to the invention is thus made. The illustration shows that the accumulation of wall material 21 of the pipe or hose 2 pressed into the receiving chamber 3 has penetrated the area between the inner side 111 of the flange stop 110 and the inner side 162 30 of the high rib 16. The second area 23 has penetrated the part of the receiving chamber 3 delimited by the free end 41 of the push sleeve 4 and the inner side 111 of the flange stop 110.

The metal tightening connector 1 is thus provided with an optimal seal 35 at the overpressure end of the push-in sleeve 4 by means of a sleeve wall provided in the longitudinal region 11 of the pipe or hose 2. This optimal closure is characterized by an optically error-free connection and a permanently liquid- and gas-tight installation of the b 9 8 3 5 6 1 injection area 11 in the central part of the pipe or hose 2.

The metal compression fitting illustrated in Fig. 2 differs from Fig. 1 in that the high rib 16 is pushed at its height H with respect to the axis of the insertion area 11 to the inner side 111 of the flange stop 110. The receiving chamber 3 then decreases when the sub-area of the receiving chamber 3 shown in Fig. 1 is filled with the metallic material of the injection area 11. In this representation, the high rib 16 also serves as a restraining response on the outer surface 161 of the sleeve of the sleeve of the pipe or hose 2.

The same points are denoted in this figure by the same reference numerals as in Fig. 1.

Fig. 2a shows the same distance Ί5 of the pressing of the push-in sleeve 4 as in Fig. 1a.

It can be seen from Figure 2b that the end position of the clamping connector 1 according to the invention with the push-in sleeve 4 fully compressed. Here, too, the free end 41 of the push sleeve 4 is located in the form of a press connection 20 on the inner side 111 of the flange stop 110. The receiving chamber 3 is formed by the free end 41 of the push sleeve 4, the inner side 111 of the flange stop 110 and the surface 114 of the high rib 16.

The tube or hose cavity material 24 transmitted by the compression pressure has penetrated the receiving chamber and in this representation partially fills the receiving chamber. This application can be used in pipes or hoses with lower manufacturing tolerances with the same optimal results as in the embodiment of Figure 1.

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Claims (2)

7 b 9 8 3 3 ^ Claims A two-part metal clamping connector for pipes and hoses made of polymeric material, provided with a pipe sleeve-shaped connector with a plug-in area with circumferential ribs to be inserted at the end of the pipe and a push-in sleeve which can be moved axially relative to the pipe shaft. , characterized in that the rib (16) turned towards the flange stop (111) extends above the ribs (12,13,14,15) at a height (H) and is formed on its outer side (161) turned towards the ribs (12,13,14,15) ) in response to the end face of the pushed tube (2), and that the rib (16) with its inner side (162), outer circumferential wall (113), flange stop (110) with inner side (111) and the free end (41) in the flange stop (110) of the push sleeve (4) form the wall of the receiving chamber (3) during compression of the push sleeve (4) material. Clamping connector according to Claim 1, characterized in that the rib (16) extends at a height (H) parallel to the axis of the insertion area (11) 20 up to the inner flange (111) of the flange stop (110). 25 30 35 8 89 8 33 ^ Patentkrav