DE8804721U1 - Dosing device for squeezing plastic masses out of tubular bags - Google Patents

Description

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A piston press is usually used to press plastic masses out of tubular bags. It essentially consists of a cylinder tube with an outlet nozzle in which the tubular bag is located and a piston which presses the contents of the tubular bag through the outlet nozzle via a coaxially mounted piston rod. Due to the coaxial arrangement of the piston rod, the overall length of the piston press is very large, particularly with long tubular bags, and the device is therefore very unwieldy.

The present invention avoids this disadvantage in that the piston is not pressed into the cylinder by a coaxially arranged piston rod, but is drawn into the cylinder via a nose located on the side of the piston, which leads through a slot in the cylinder tube wall.

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Figure 1 shows an embodiment of the invention. The tubular bag 2 (shown in dashed lines) is located in the cylinder tube 1. The lower end of the cylinder tube 1 is closed by a union nut 3 with a thread or bayonet catch. The outlet nozzle k is located in the union nut. The squeezing piston is mounted at the upper end of the cylinder tube. It consists of the pressure piston 5, the guide piston 6, the connecting plate 7 with the nose 8 which reaches through the slot 9 of the cylinder tube 1 and has a threaded nut 10 at the lower end. The threaded spindle 11 runs in the threaded nut. It can rotate with its lower end in the radial bearing 12, but is axially fixed. The radial bearing sits firmly with its outer ring in the housing 13. A 2*helical gear 1*f is firmly connected to the upper end of the threaded spindle 11. The pinion 13 of the electric motor is in engagement with the gear wheel 1*f. The housing 13 is provided with a pistol grip 1?. In the pistol grip there is a pressure piece 18 which actuates a switch 19. This switch 19 can, in addition to an on and off function, also carry out an additional speed control for the motor 16. By means of a changeover switch (not shown here), it is possible to change the direction of rotation of the motor 16 and thus also the direction of movement of the pressing piston.

Figure 2 shows the cross section a - a through Figure 1. It can be seen that the housing 13 consists of two axially divided halves 2o and 21.

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Figure 3 shows the squeezing piston from Figure 1 with the difference that a guide roller 22 is arranged instead of the guide piston 6.

Figure 4 shows a design of the dosing device, in which the axial movement of the squeezing piston is effected by a roller chain. The squeezing piston again consists of the pressure piston 30, the guide piston 31, the connecting plate 32 with the nose j>5, which engages through the slot i>h of the cylinder tube 35 and is positively connected to the 4-roller chain 36. The chain is guided over the chain wheels ¥J and ji8. The chain wheel J58 is firmly connected to the worm wheel >9, which is driven by the motor 41 via the worm ko . Instead of the roller chain, a toothed belt or similar can also be used. This arrangement has the advantage of being more efficient than an arrangement with a threaded spindle. The efficiency can be further increased if a spur gear is arranged instead of the worm gear.

The dosing devices according to Figure 1 and Figure k can of course also be operated manually instead of with a motor, for example by operating the threaded spindle 11 in Figure 1 with a hand crank &bull;which drives the chain wheel 38 in Figure 4 directly with a hand wheel.

A particularly advantageous arrangement for manual operation is shown in Figure 5. The squeezing piston consists of the pressure piston 5o, the guide piston 51 and the connecting plate 52. The connecting plate has two bent guide lugs

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And 5^t which at the same time are abutments for the Vye^kaflWitifcUiige 55. Another wide guide nose $6 forms together with the lower bent edge 57 of the roller 58 with pressure spring and the square rod 55 a clamping roller freewheel. The three guide noses 53» 5 ¹ * and 56 are guided in the slot 60 of the cylindrical tube 61. The freewheel is actuated via a lever 62 iffl pistol grip 63 on the push rod 64, which acts on the square rod via the bolt 65.

If the lever 61 is pressed into the pistol grip 62, the square rod ^ moves with the ejection piston in the direction of the discharge nozzle 66. When the lever 61 is released, it is pressed back into its starting position with the push rod 6k and square rod 55 by the spring 67. The ejection piston remains stationary due to the effect of the roller freewheel. The return movement of the ejection piston is prevented by the retraction lever 68 with tension spring 69 because the retraction lever 68 is arranged by its pivot point in the connecting plate 52 in such a way that it performs a freewheel function in the opposite direction to the roller freewheel. When the ejection piston:a has reached its lower position, it must be pulled back again by hand using the cable 71. However, this is only possible if the freewheel effect of the roller freewheel has been canceled. Therefore, the retraction lever 68 has a nose 72. This engages in a corresponding nose 73 of the lever 7h , which is moved about the pivot point 75 and with its free bent end 76 presses the roller 5Ö out of the clamping position and thus renders the freewheel ineffective.

Claims (1)

Expectations Claim 1 Dosing device for squeezing plastic masses out of tubular bags, characterized in that the pressure piston, consisting of the pressure piston (5), the guide piston (6), the connecting plate (7) is pulled into or out of the cylinder tube (1) by the nose (8), which reaches through the slot (9) of the cylinder tube (1). Claim 2 Posing device for squeezing plastic masses out of plastic bags according to claim 1, characterized in that the nose (8) of the squeezing piston is provided with a threaded nut and is pulled into the cylinder tube (1) by a threaded spindle (11). Claim J5 Dosing device for squeezing plastic masses out of tubular bags according to claim 1, characterized in that the nose (}$) of the squeezing piston is positively or non-positively connected to a roller chain (^o). Claim k Dosing device for squeezing plastic masses out of tubular bags according to claim 1, characterized in that the broad nose (56) with its lower edge (57) of the roller (58), the spring (59), the two noses (5.5) and (5^) and the square rod forms a clamping roller freewheel. Claim 5 Dosing device for squeezing plastic masses out of tubular bags according to claim 1, characterized in that the squeezing piston has a guide roller (22) instead of the guide piston (6). Claim 6 Dosing device for squeezing plastic masses out of tubular bags according to claim 1, characterized in that the housing (iji) consists of two axially divided halves (2o) and (21).