DE1557278C - Head washer - Google Patents

Description

There is already a head washing system with vertical axis swivel arm joints known in which the Washbasin rotatably and vertically displaceable arranged at the free end of an upper pivoting pan is, the other end to the free end of a pivotable about a fixed point lower Arm is articulated, these joints by means of an eccentric hand lever mounted on the middle joint, by means of axially displaceable lifting rods with wedge surfaces and provided with wedge sliders horizontally movable brake rods can be locked and released (German Auslegeschrift 1196 826).

When these three joints are determined, however, the movement processes overlap in the joints, which has the consequence that the force required must be greater than if the individual joints were determined separately.

In order to reduce the effort required to operate a head washing system compared to the ao To reduce the size occurring in the known system, a system of the described known Kind be characterized according to the invention that the detection and resolution of the individual brake members during a continuous eccentric lever movement in three different times takes place at separate intervals, with the movement of the hand lever out of its all joints releasing rest position in a working position that establishes all joints

a) an eccentric disc of the hand lever releases a wedge sleeve, which is then activated by a compression spring is axially displaced and a push rod by means of a wedge slide the one Joint (I) establishes

b) then an eccentric crank pin on the hand lever extending lengthways through the wedge sleeve Pull rod with a wedge bushing coaxial to it against the force of a compression spring moves and a push rod fixes the other joint (IH) by means of a wedge slide,

c) then the eccentric crank bolt a cone coupling between the two the pull rod coaxially encompassing, one on the other rotatable and longitudinally displaceable sliding, the third joint (II) engages forming tubes against the force of a compression spring and thereby the third joint (Π) detects and

d) then the crank bolt raises the tie rod under tension from the spring located between it and the wedge bushing until it exceeds its top dead center. ^;

An embodiment of the invention is described below with reference to the drawing, in which one

Fig. 1 is a side view of the system without later represents cladding to be mentioned,

Fig. 2 and 3 illustrate details of the structure of the system,

Fig. 3a serves to explain the mode of operation,

Fig. 4 shows the system including its casings and

A b b. 5 represents a top view of the system according to Fig. 4 in solid lines and in dotted lines

55 lines a plan view of the system in an operationally occurring swiveling position of the head washbasin.

As in A b b. 1 shown is a drawn in section Head wash basin 10 by means of a basin support 11 on the also shown in section upper end of a stand tube 12 attached, which is both rotatable and displaceable up and down within a guide sleeve 13. This Stand tube 12, together with guide sleeve 13, forms the pivoting and sliding joint of the boom. This. Let the joint be denoted by I.

On the guide sleeve 13 there is now an upper extension arm 14 attached, at the left end of a vertical tubular shaft 15 is attached. This tubular wave 15 forms, together with a joint bushing 16 in which it is rotatable, a second swivel joint II.

At the lower end of the joint bushing 16, the left end of a lower boom arm 17 is attached, at the right end of a downwardly extending pipe pin 18 is attached. This pipe stud 18 forms, together with a stand tube 19 attached to the floor, a third joint III, which is also a vertical axis swivel joint.

A hand lever 20, which can be adjusted within an angular range of approximately 120 °, makes it possible now, as shown in A b b. 2 and 3 will be explained below, the vertical axis pivot and sliding joint I and the two vertical axis pivot joints II and III in three different times at separate intervals. For power transmission from joint II to the two joints I. and III serve push rods 21 and 22 in a manner to be explained in more detail. A in A b b. 1 The rubber hose 23 still contained serves to drain the sewage from the wash basin and the components 24 to 26 have the purpose of balancing the weight of the relatively heavy head washbasin 10 to create. However, this sewerage and this weight compensation are in the following are not explained in more detail.

Using the A b b. 2 and 3, with the aid of Fig. 3a, the determination of the individual Joints are explained. The hand lever 20 is connected to an eccentric disk 27, which is mounted in vertical brackets 29 by means of stub shafts 28. The eccentric disk 27 also carries a second eccentric in the form of a crank bolt 30.

The hand lever 20 is in A b b. 1 and 2 shown in the position in which all joints are fixed. To solve or release all joints, this hand lever is in A b b. 1 and 2 to rotate 120 ° to the left, and the determination of the individual joints should be from this starting position in the following on the basis of A b b. 3 a, which represents the path of the crank pin 30 around the center point M of the stub shafts 28, are explained. In the left limit position of the hand lever 20, the crank pin is located at point A on a dotted top drawn around the center point M of the stub shafts 28. The radius A -M includes an angle of 25 ° with the horizontal. The circumference of the eccentric disk 27 then rests on the upper end face of a guide bushing 31 and presses this guide bushing 31 against the force of a helical spring 32, which is inside the tubular

WellelS is housed, down. The push rod 21 is thus under the force of a spring 32a with its wedge slide located at the left end

33 on the inclined surface of the guide bush 31, so that a brake pad 34 is lifted from the stand tube 12 and the stand tube is thus freely rotatable and displaceable within the guide sleeve 13.

If the hand lever 20 is now moved from its left limit position to the right, the circumference of the eccentric disk 27 withdraws from the upper end face of the guide bush 31, while the crank pin 30 migrates from A to B , so that at point B in A b b . 3 a the guide bushing 31 by the helical spring 32 already in the in A b b. 2 position shown has been pushed upwards and has thereby moved the wedge slide 33 to the right. The brake pad is thereby over the push rod 21

34 pressed against the force of the spring 32 a on the stand tube 12, and the joint I is thus determined. -

In the further course of the movement of the hand lever 20, the crank pin 30 now moves on the circle K in A b b. 3 a from B to C and lifts over a pull rod linked to the crank pin 30

35 a wedge bushing 36 approximately in the in A b b. 2 drawn Location. For this purpose, the tie rod 35 is at its lower end with the inside a collar sleeve 37 connected by a screw thread. On the outside of the cylinder this one Disc springs 38 are attached to the collar. These disc springs are between a washer 39, who are involved in one of the A b b. 2 level, not shown, is supported on the cylinder part of the collar sleeve 37, and a second washer 40 by means of a mutler 41 preloaded.

In the position shown, the wedge bushing 36, ie at point C of A b b. 3 a, is by means of a wedge slide 42, which is attached to the inclined surface of the wedge bushing

36 is applied, and a brake pad 43 is pressed against the force of a helical spring 44 against the stator tube 19 via the push rod 22. At point C in A b b. 3 a, the lower joint IH is also established.

If you now move the hand lever further, i.e. if you try to go through the path CD on the top in Fig. 3a, the pull rod 35 will initially not move any further up, since the inclined surface of the wedge bushing 36 is already in contact with the wedge slide 42, and therefore, when a force continues to be exerted on the hand lever, the vertical tabs 29 and thus the tubular shaft 15 are pressed downward. This latter movement takes place against the force of disc springs 45 which are arranged in the interior of the tubular shaft 15. These disc springs rest on the upper edge of a support tube 46, which is screwed with its lower end into a base pin 47 of the joint bushing 16. So while the crank bolt 30 traverses the path CD in Fig. 3a, the tubular shaft 15 moves downward under the tension of the disc springs 45 until a cone coupling engages the conical surfaces 48 and 49 between the tubular shaft 15 and the joint bushing 16. This is the case at point D in Fig. 3a, and at this point in the movement of the hand lever, joint II is now also established.

With the further movement of the crank pin 30 beyond the point D, only a very go through a small vertical path, and this path is taken up by tensioning the disc springs 38 on the collar 37. The wedge bushing 36 is pressed even more firmly against the wedge slide 42 and the brake pad 43 is tightened even more.

When the crank bolt 30 has passed its uppermost waypoint on the circle K , the crank bolt 30 is held in the limit position E by the force of the plate springs 38, which may have an angular distance of 5 ° from the vertical through the point M. At the same time, the hand lever is in his right in A b b. 1 and 2 shown limit position.

The foregoing should show that the determination of all three joints at an arrangement according to the invention takes place in three time-separated intervals. So it takes not the sum of the forces required to locate joints II and III are used, and the force required to lock the joint I during the locking interval for the Joint I is delivered by relaxing the spring 32, is during the last part of the unlocking stroke of the hand lever 20, so separate from the to apply the respective effort to determine the joints II and III.

If you want to cancel the fixing of the various joints again, the hand lever 20 is made from the position shown in A b b. 1 and 2 position shown again moved to the left. This relaxes during the travel of the crank bolt 30 from E to D in A b b. 3a first the disk springs 38, and the relaxation of the disk springs 45 occurring on the way from D to C, the tubular shaft 15 is moved upwards again, the cone coupling 48, 49 thus released. The stroke of this cone coupling is limited by what is known as a hold-down device 50, which is screwed onto the joint bushing 16 and engages with a nose in a groove 51 on the outside of the tubular shaft 15. The joint II is now released again.

During the further travel of the hand lever 20, the crank bolt 30 passes on the circle K in A b b. 3 a the way CB. The wedge bushing 36 is lowered again via the tie rod 35, since the upper collar of the collar bushing 37 rests against the inner surface of the bottom of the wedge bushing 36 and presses the wedge bushing downwards. The spring 44 can therefore move the wedge slide 42 to the left again, so that the brake pad 43 is lifted off the stator tube 19. Joint III is now also released again.

Finally, on the way BA of the crank pin 30 in A b b. 3 a the circumference of the eccentric 27 press the guide bush 31 against the force of the helical spring 32 back down, so that the brake pad 34 can then be lifted from the stand tube 12 by the helical spring 32 a and the push rod 21 is opposite to the in A b b . 2 position shown again moved to the left. The joint T is thus now also released again.

After releasing all joints, the system can be shown in Fig. 4 and 5 by solid lines shown rest position are brought. In these figures, casings 52 are also shown, which are used to cover the upper extension arm, the lower extension arm, the joints and the stand

serve the foot and one of which is opposite to each other Cladding halves are braced against one another by means of screws 53.

Claims (1)

Claim: Head washing system with vertical-axis swivel arm joints in which the washbasin can be rotated and is arranged vertically displaceably at the free end of an upper pivot arm, the other end to the free end of a lower arm pivotable about a fixed point is articulated, these joints by means of an eccentric hand lever mounted on the middle joint, by means of axially displaceable lifting rods with wedge surfaces and through with wedge slides provided 'horizontally movable brake rods can be locked and released, characterized in that that the determination and release of the individual brake members during a continuous eccentric lever movement in three takes place at separate intervals, with the movement of the hand lever from its rest position releasing all joints into a working position that detects all joints a) an eccentric disc (27)
(20) a wedge sleeve (31) of the hand lever releases which 25 is then axially displaced by a compression spring (32) and a pressure rod (21, 34) that fixes a joint (I) by means of a wedge slide (33), b) then an eccentric crank pin (30) on the hand lever (20) one longitudinally through the Wedge sleeve (31) extending tie rod (35) with a wedge bushing coaxial to it (36) moves against the force of a compression spring (38) and by means of a wedge slide (42) a push rod (22, 43) secures the other joint (III), c) then the eccentric crank pin (30) a cone coupling (48, 49) between the both coaxially encompassing the tie rod (35), rotatable and longitudinally displaceable on one another sliding tubes (15, 16) forming the third joint (II) against the force of a compression spring (45) for engagement brings and thereby the third joint (II) establishes and d) then the crank bolt (30) the tie rod (35) under tension between it and the spring (38) located in the wedge bushing (36) continues to rise until it reaches its top dead center exceeds. 1 sheet of drawings