NO163469B - HANDLE OPERATING SWITCH AND MULTIPLE SWITCH BLOCK DESIGNED BY PARALLEL AT THE SIDE OF OTHER LOCATED SWITCHES. - Google Patents

Abstract

1. A manually operated fuse switch (1) with a switch rocker (16) and a duct (4) accommodating the fuse link (5), whose switch rocker (16) covers the duct (4) for the fuse link (5) when the switch (1) is in the switched on position, - the switch rocker (16) - having a lever type design, - comprising an actuating arm (46) and a drive arm (45) and - the drive arm (45) being locked in the open position of the switch rocker (16) by a catch (56) when the fuse link (5) has been removed or incorrectly inserted, characterized in that the actuating arm (46) of the switch rocker (16) comprises a knee joint (49) subdividing the actuating arm (46) into an inner arm (47) and outer arm (48), which knee joint is spring loaded against the switching on direction (41) of the rocker.

Description

The present invention relates to a hand-operated safety switch with a switch handle and a shaft that accommodates a fuse insert, where the switch handle in the engaged position of the switch covers the shaft for the fuse insert shaft, where the switch handle is rod-shaped, and includes an engagement arm and a drive arm, where the drive arm when removed or not correctly inserted fusible link in the off position of the switch lever, is blocked via a buffer.

Circuit breakers of this type are arranged in blocks in a row and are particularly used as household fuses in low-voltage areas. The invention thus also relates to a multi-pole switch block formed by parallel, side-by-side fuse switches.

Such known switches, such as e.g. is shown in DE off. document no. 29 34 149 or DE off. document no. 26 18 360, shows on the upper side of the switch's housing a flap-shaped switch lever, with which the switch arranged in the housing is operated manually. In the closed position of the switch, the shaft of the fuse insert is covered by the switch lever. Therefore, when replacing fuses, the switch lever must first be brought to the open position, whereby the supply-side contact of the fuse insert is disconnected from the mains. Correspondingly, if the fuse protection insert is not inserted or not inserted correctly, a shut-off mechanism is activated, which blocks the switch lever in its open position. Thereby, an increased safety against contact is achieved.

The invention is based on experiences with the above-mentioned switches, in that in practice its shut-off mechanism can be destroyed by a strong impact of the switch lever. This further leads to functional incapacity for the switch, or even worse, to a closing of the switch, through which, despite the incorrect or improperly inserted fuse insert, the supply-side lower contact on the fuse base can be energized. Especially when an electrical consumer is protected differently via block-wise, side-by-side circuit breakers, can. consumer parts that include parallel circuit breakers that are equipped with a regulated fuse insert are energized, even if there is an obvious fault in the consumer's circuit.

The purpose of the invention is to produce a safety switch of the type mentioned at the outset, where the safety switch's shut-off mechanism is effectively protected against destruction by strong hand grips on the switch handle.

This is achieved according to an embodiment of a hand-operated safety switch which is characterized in that the switch lever's engagement arm is spring-loaded opposite to a connection direction, and the engagement arm is divided into an inner leg and an outer leg via an angle joint.

Advantageous further developments and further constructive characteristics of the invention are indicated in the other claims.

.'According to the invention, an angular joint is provided in an engaging arm, which is thereby not rigid. If the securing insert is separated and the switch lever is thereby blocked, the angle joint is broken from the tension position against the spring load in its breaking position by a strong engagement of the switch. In this way, the storage is affected with full engagement force via the switch lever in the case of traditional

circuit breakers due to the fact that the torque ratios are multiplied, but are only loaded with a fraction of the engagement force with the spring load.

According to a particularly suitable solution, the angle joint is pressed upwards in the stretching direction by a pivot spring which is arranged coaxially with the joint's axis of rotation. In particular, the torsion spring can be integrated into the joint, which gives it a particularly compact and space-saving design. Due to the particularly chosen spring constant, a switch according to the invention is provided which functions without problems. By the fact that the transferable force is greater than that to overcome the switching force, a safe closing of the switch by regulated insertion of the fuse fuse is always possible. If the switch lever is blocked, only a fraction of the attack force is transferred via the spring to the bearing. With the chosen version of the spring, this force is so small that there is no danger of destroying the switch's bearing. Therefore, the switch lever behaves like traditional fuse switches when the safety insert is correctly inserted. For untrained staff, there will thus be no change in operation. The particularly safety-technical, advantageous design of the safety switch according to the invention first appears in the event of incorrect operation.

When the angle joint is arranged in the inward area of the engagement arm near the axis of rotation of the switch lever, a switch engagement can only follow over the break-resistant outer leg of the engagement arm. When the inner leg is very short, no attack surface is provided for engagement with the switch. Furthermore, as a result of the arrangement of the angle joint in the vicinity of the pivot point, relative to the storage location, rod designs are approximately identical. These simplify the selection of torsion springs, in that their spring constant is only selected so that the maximum transferable force is less than the breaking force from the storage location. Complicated calculations due to different handle designs can therefore be dispensed with.

According to a preferred embodiment, the angular joint is protected against external attacks and unspeakable manipulations. As the rotary cutters do not stand above the contour surface of the switch handle, its pointed end cannot cause damage to operating personnel.

Furthermore, contact surfaces can be arranged in the direction of buckling behind the angle joint so that the inner leg and the outer leg have opposing contact with each other, thereby effectively avoiding that the angle joint is overstretched when the switch lever is moved in the opening direction. By means of the angled design of the stop rafts (according to claim 10), a stable structure of the angular joint is achieved. These properties are further substantiated through the characteristic features according to claim 11. According to the invention, therefore, a safety switch is proposed, which in sum of advantages is highly functional and extremely well protected against damage.

The safety switch exhibits special advantages over known types, when several are combined into a switch block which is characterized by the fact that the switch handles are coaxially supported and the drive arm, respectively the inner leg of the engaging arms relative to the engagement and disengagement turning movement are rigidly connected to each other. Namely, if only one fuse insert is not inserted or not inserted correctly, all fuse switches are blocked by means of the shut-off mechanism placed in this fuse block and the rigid connection between the drive arms. When all the engagement arms of the switch lever are secured via an angle joint, it is not possible to destroy the storage and to put the consumer that is connected after the circuit block fully or partially under current. This constitutes a significant safety advantage compared to known switch blocks. A particularly advantageous and simple construction is described in claims 13 and 14. The entire block is operated by a single switch lever, which is secured via an angle joint.

The invention will now be described in more detail with the help of an embodiment and with reference to the accompanying drawings, in which: Fig. 1 shows a view of a circuit breaker's open half with the fuse inserted in accordance with regulations and a load switch in the engaged position. Fig. 2 shows a diagram corresponding to fig. 1 with the fuse insert removed and with the switch lever and load switch in the disengaged position. Fig. 3 shows a view corresponding to fig. 1 and 2, with the fusible link removed in the event of implied intervention by a switch lever present despite a blockage.

The entire safety switch, which is given the numerical reference 1, is assembled from two housing halves 2 which are made of an insulating material, as indicated in the figures. A dividing joint between the house halves 2 runs in the drawing plan of the figures. The end parts of both housing halves are connected to each other by riveting. The rivets thus protrude through through-holes 3. The fuse switch 1 contains a shaft 4 to accommodate a fusible link insert 5. Connection terminals 6, 7 serve to cut off current via the fusible link insert 5. The connecting terminal 7 is electrically conductively connected to a screw frame 8 over a conductor 10, in which a screw cap 11 with its holder cap's 9 threads can be screwed in.

The fuse insert 5 is equipped at its upper and lower end with end contacts, namely an upper contact crown 12 and a lower contact crown 13. When the screw cap 11 is screwed in according to regulations, a conductive contact is provided between the screw cap 11 and the fuse insert 5's upper contact crown 12. The fuse insert 5's lower contact 13 lies in the drawing plan of the figures and is movably arranged against the counter contact 14 arranged inside the housing. The contact chip 15 lies at the on-load switch (fig. 1) at both of its contact parts 17, 18 against the opposite contact ends 19, 20 of the fusible link insert's opposite contact 14, i.e. against a contact tap 21 connected to the connection terminal 26.

The contact chip 15 is pressed upwards via the pressure from tension springs 22, 23 in the direction towards the opposite contact ends 19, 20, i.e. in the direction towards the switch-on position. The tension springs 22, 23 are supported with their lower end against a house wall 24.

A pressure rod 25, which consists of an insulating material, lies with its front end against the upper side of the contact chip 15. The pressure rod 25 which is supported in the tension springs 22, 23 in the direction of pressure, i.e. at right angles to the longitudinal direction of the contact piece 15 and between the walls of the housing 27 and longitudinally displaceable on the inside of the safety switch 1. When it is supported from the contact piece 15, it lies in an inserted position in the space between the contact piece 15 electrically conductive and mutually connected opposite contact ends 19, 20.

The switch rocker 16 is pivotally supported on a pivot shaft 28 on the circuit breaker 1, which runs vertically on the drawing plane. It is equipped at its end 29, which faces the push rod 25, with an outlet 30 for receiving the switch lever-shaped control rod, which is hereinafter referred to as switch lever rod 31, and a rod 32 designed for the switch lever rod 31, and where the whole is equipped with a angle rod arm 33. The free end of the switch rocker rod 31 is pivotally supported about the pivot axis 28 of the switch lever 16. The rod 32 serves as a pressure transfer part and rests with its free end 34 against the rear side of the pressure rod 25 which faces away from the contact piece 15. The free end 34 of the rod 32 rests in a groove 35 on the rear side of the push rod 25, which can be pivoted in a certain angular progression. As the contact piece 15 and the pressure rod 25 are pressed upwards by the tension springs 22, 23, the rod 32 with its free end 34 lies permanently in the groove 35.

When transferring the switch lever 16 from the engaged position (fig. 1) to the disengaged position (fig. 2), the angle rod arm 33 is pushed through via a tension rod (not shown) via contact with the outlet 30 on the lower end of the switch lever 16. Thereby, the joint axis of the angle rod arm is moved downwards in the direction of the contact piece 15. Via the rod 32, the push rod 25 is thereby pressed downwards (arrow direction 26) and the contact piece 15 is lifted by the counter contacts 19, 20.

In what follows, the structure and operation of the switch lever 16 shut-off device will be described in more detail. It essentially consists of a shut-off bracket 37 extending in the direction of the arrow 26, which with its contact end 38 is attached to the shaft 4 in the edge area of the contact chip side. The free end 39 of the shut-off bracket 37 is located in the surrounding area of the end 29 of the switch lever 16. With the switch lever 16 in the disengaged position, the outlet 30 lies above the free end of the shut-off bracket 37. The counter contact 14 of the fuse insert 5 is pressed upwards on its underside via a contact spring 40, which is supported at its lower end. the housing wall 24. With the switch lever 16 in the disengaged position (fig. 2), the outlet 30 lies above the free end 39 of the shut-off bracket 37. If the fusible link 5 is now broken, the the counter contacts lifted upwards via the pressure from the compression spring 40 and the free end 39 of the shut-off bracket 37 is pushed into the outlet 30. When the switch lever 16 is moved in the engagement direction 41, the free end 39 of the shut-off bracket 37 comes into contact with the rim 42 of the outlet 30, whereby the switch lever 16 is blocked .

This situation is shown in fig. 3.

Fig. 3, on the other hand, will subsequently explain the structure and operation of the switch lever 16. The switch rocker 16 is designed as a lever and is rotatably supported about a pivot axis 28 in the safety switch 1. It is essentially L-shaped, whereby the L -shaped horizontal angle leg 43 at its free end passes into a cylinder roller 44 which is arranged concentrically with the axis of rotation 28. The cylinder roller 44 has, at its contact-side circumferential area, the outlet 30 which the shut-off hoop 37 engages in if the fuse protection insert 5 is not inserted or not correctly inserted and in which the switch lever rod 31 is located. The contact-side part of the cylinder roller 44 thus serves as a drive arm 45 on the angle rod arm 33 and thereby engages the contact piece 15 above the pressure rod 25. The contact-side part of the cylinder roller 44, together with the L-shaped angle leg, is designated as the engagement arm 46. The engagement arm 46 is divided via an angle joint 49 into an inner leg 47 and an outer leg 48 via the transition area between s the cylindrical roller 44 and the horizontal angle leg 43. The angle joint 49 is pushed upwards by a pivot spring 51 which is supported concentrically about a joint axis 50 opposite the switch lever 16's engagement direction 41. The upward force is transmitted via the pivot spring 51's free ends 53, 54, by these being against the inner leg 47 and the outer leg 48, respectively, which faces in the direction of buckling 55. The torsion spring exhibits such a spring force constant that it transmits a greater force than is needed to overcome the engagement force, but which is less than the blocking force that the shut-off bracket 37 applies to a bearing 56. thus retained (fig . 1) the angle joint 49 via the spring load substantially in its stretched position during an engagement sequence when the switch lever is not blocked. If the switch lever is blocked (fig. 3), the angle joint 49 is brought over to its bent position. Fig. 3 shows a particularly advantageous embodiment in the construction of the switch lever 16 with the angle joint 49. The angle joint 49 is namely located in the transition area between the cylinder roller 44 and an L-horizontal angle leg 43 projecting recess 57, without the free ends 53, 54 of the torsion spring appearing above the outline surface of the switch lever 16 . From the recess 57, a parting joint 58 protrudes outwards in the area of the cylinder roller 44. The inner leg 47 and the outer leg 48 have mutually facing abutment surfaces 59, 60, which in the angle joint 49's stretched position (fig. 1) rest against each other. The angular shape of the abutment rafts 59, 60 is advantageously designed in such a way that movement forces acting in arbitrary directions can be distributed evenly over the fixed abutment of the angular surface. The special design of the switch rocker 16 with L-shaped part and cylinder roller 44 also provides an increased size of the opposing contact surfaces 59, 60, whereby the occurring specific surface pressure is further reduced.

Furthermore, parallel fuse switches arranged next to each other of the type shown in figures 1-3 can form a multi-pole switch block. With such switch blocks, the individual switch levers 16 are coaxial about a pivot axis 28. The advantage according to the invention is that the inner arms 47 of the engagement arms 46 and the cylinder rollers 44 of the drive arms 45 are rigidly connected to each other. In practice, it is thereby achieved that the fuse block's individual fuse switches 1 are designed in common, and a continuous cylinder roller 44 can be used. Via this rigid connection, it is guaranteed that when a circuit breaker 1 is switched off, when the adjacent shut-off bracket 37 engages in an outlet 30, the entire fuse block is switched off. As the outer arm 48 of the switch lever 16 can be bent down via the angle joint 49, neither the fuse block nor the support 56 can intervene because transferring the switch lever 16 to the engaged position by force means that it is destroyed.

Via the rigid connection to the outer link 48 of the engagement arm 46 in the individual safety switches, this works in a uniform manner

as a multi-pole fuse block, whereby the shut-off function in case of not inserted or not correctly inserted fusible link insert 5 for a single pole, prevents intervention for the entire block. In that case

the rigid connection between the cylinder rollers 44 is saved for assembly into one part. Namely, if only one drive arm 4 5 is blocked by means of the support, not only is a buckling torque transmitted to all angle joints via the outer legs' rigid connection with each other, but no engagement torque is transmitted to the non-blocked drive heaters.

Claims (14)

1. Hand-operated safety switch (1) with a switch lever (16) and a shaft (4) that accommodates a fuse insert (5), where the switch lever (16) in the engaged position of the switch (1) covers the shaft (4) for the shaft of the fuse insert (5) (4), where the switch lever (16) is rod-shaped, and includes an engagement arm (46) and a drive arm (45), where the drive arm (45) when the fuse protection insert (5) is removed or not correctly inserted in the switch lever (16)'s position, is blocked via a bearing (56), characterized in that the engagement arm (46) of the switch lever (16) is spring-loaded opposite to an engagement direction (41), and the engagement arm (46) is divided via an angle joint (49) into an inner leg (47) and a outer leg (48). 2. Safety switch in accordance with claim 1, characterized in that the bending direction (55) of the angle joint (49) corresponds to the engagement direction (41) of the switch lever (16). 3. Safety switch in accordance with claim 1 or 2, characterized in that the spring which produces the spring load on the angle joint (49) is a pivot spring (51) arranged coaxially with the joint axis (50) of the angle joint (49), and that its free ends (53, 54 ) on the inner side of the engagement arm (46) inner leg (47) and on the opposite side of the outer leg (48) press upwards in the direction of buckling (55). 4. Safety switch in accordance with claim 3, characterized in that the rotary spring (51) exhibits such a spring constant that the transferable force is greater than that to overcome the engagement force, but is less than the locking force of the support (56), that the course of movement when the switch lever is not blocked (16) is such that the angle joint (49) is essentially held firmly in its extended position via the spring load and when the switch lever (16) is blocked, the angle joint (49) is transferred to its bent position. 5. Safety switch in accordance with one of the preceding claims, characterized in that the angle joint (49) is arranged lying on the inside of the area of the engagement arm (46) in the vicinity of the pivot axis (28) of the switch handle (1.6). 6. Safety switch in accordance with one of the preceding claims, characterized in that the switch lever's engagement arm (46) is L-shaped and in the engaged position covers the shaft (4) and in the disengaged position releases the shaft (4), at the angle joint (49) is arranged on the inside of the L-horizontal angle leg (43) containing joint axis (50). 7. Safety switch in accordance with claim 6, characterized in that the L-horizontal angle leg (43) has an outlet (57) in its bending direction (55) opposite inner side in which the angle joint (49) is located. 8. Safety switch in accordance with claim 7, characterized in that the rotary spring (51) is arranged on the inner side of an L-outline surface. 9. Safety switch in accordance with one of the preceding claims, characterized in that the inner leg (47) and outer leg (48) of the engagement arm (46) are arranged on the side of the bending direction behind the angle joint (47) and have opposite contact surfaces (59, 60) for mutual facility. 10. Circuit breaker in accordance with claim 9, characterized in that the contact rafts are angularly designed and in the tension position the angular joint is substantially fixed to each other. 11. Safety switch in accordance with one of the preceding claims, characterized in that the inner leg (47) of the engagement arm (46) and the drive arm (45) together form a rotationally mounted cylinder roller (44). 12. Multi-pole switch block formed of parallel, side-by-side safety switches (1) in accordance with the preceding requirements, characterized in that the switch handles (16) are coaxially supported and the drive arm (45), respectively the inner leg (47) of the engagement arms (46) relatively until the engagement and disengagement turning movements are rigidly connected to each other. 13. Multi-pole switch block formed by parallel, side-by-side fuse switches (1) in accordance with one of claims 1-11, characterized in that the engagement and disengagement positions of the outer legs (48) of the engagement arms (46) are rigidly connected to each other. 14. Multi-pole switch block in accordance with claim 13, characterized in that the outer legs (48) are produced in one piece of a synthetic material.