TECHNICAL FIELD The present disclosure relates to a pickup mechanism for feeding of weld pins from a magazine to a welding electrode of a welding gun. The pickup mechanism is attachable to the welding gun in connection to the welding electrode and the magazine is attachable to the pickup mechanism. The disclosure further relates to a system for welding and a method for feeding of weld pins.

BACKGROUND

Weld pins are commonly used for attaching an insulation material or similar structure to a construction surface made of metal, such as for example ventilation ducts or other steel structures of buildings, ships or off-shore constructions. The insulation material can for example be a liner for heat or fire insulation. The weld pin is designed with a nail part having a nail tip that is stud welded to the construction surface. Traditionally, when welding the weld pins to the construction surface, the weld pins are fed manually from a stock of weld pins to a welding electrode of a welding gun. The stock of weld pins may for example be a weld pin cartridge, box or pocket, where the weld pins are stored. At the welding electrode of the welding gun, the weld pin is held in position by a magnet. The manual feeding of the weld pins to the welding gun makes the work time consuming and inconvenient for the operator of the welding gun. In US 5,824,987 a weld pin feeder and a magazine is disclosed, where the magazine is provided essentially parallel to the welding axis, and a lever with a permanent magnet picks up the weld pins from the magazine and guide them to the welding electrode. One problem with his solution is that the construction is not ergonomically adapted to the operator. The solution described in US 5,824,987 may be complicated to use when welding in corners of a construction structure or when welding in small or tight spaces, such as close to pipes or other construction elements. Further, the feeding of weld pins is not precise enough to secure an efficient feeding of the weld pins to the welding gun.

There is thus a need to make the handling of welding guns faster and more convenient to the operator, through a more efficient and precise feeding of the weld pins, which welding gun is ergonomic to use and adapted for being used in tight spaces.

SUMMARY OF THE DISCLOSURE

An object of the present disclosure is to provide an improved pickup mechanism for feeding of weld pins, a system for welding, and a method for feeding of weld pins, where the previously mentioned problems are avoided. This object is at least partly achieved by the features of the independent claims. The dependent claims contain further developments of the pickup mechanism for feeding of weld pins, and the system for welding. The disclosure concerns a pickup mechanism for feeding of weld pins from a magazine to a welding electrode of a welding gun, where the pickup mechanism is attachable to the welding gun in connection to the welding electrode, and where the magazine is attachable to the pickup mechanism. The pickup mechanism comprises a movable pickup lever arm displaceable between a pickup position and a delivery position, where the pickup lever arm is adapted for displacing the weld pin from a pickup position in the magazine to a welding position at the welding electrode. The pickup lever arm has a pickup part comprising a feeding portion for feeding the weld pins from the pickup position to the welding position. The pickup part comprises a retrieving portion arranged with a sliding surface for displacing the pickup lever arm in a direction essentially perpendicular to the direction of the movement between the delivery position and the pickup position when the sliding surface is in contact with a first weld pin in the magazine, and when the pickup lever arm moves between the delivery position and the pickup position to pick up the first weld pin. The pickup part is configured such that the sliding surface bridges the first weld pin to the feeding portion at a predetermined position of the pickup lever arm, and such that the first weld pin engages the feeding portion in the pickup position.

Advantages with these features are that the handling of the welding gun is faster and more convenient to the operator through a more efficient and precise feeding of the weld pins. The welding gun will also be more ergonomic to use and adapted for being used with one hand only with a pickup mechanism that is having a compact construction with a feeding portion arranged for feeding the weld pins from the magazine to the welding electrode.

According to an aspect of the disclosure, the pickup lever arm is displaced from the pickup position to the delivery position when the pickup lever arm is tilted in a first rotational direction around a first rotational axis. The pickup lever arm is displaced from the delivery position to the pickup position when the pickup lever arm is tilted in a second rotational direction around the first rotational axis. The second rotational direction is opposite the first rotational direction. These features provide an efficient and secure feeding of the weld pins from the magazine to the welding electrode that is fast and simple.

According to another aspect of the disclosure the feeding portion has an arc- formed concave shape, which when the pickup part is arranged in the pickup position is adapted to engage the first weld pin such that the first weld pin can be lifted by the feeding portion from the pickup position to the welding position. The shape of the feeding portion secures that the weld pins are fed from the magazine to the welding electrode in an efficient and reliable manner. According to a further aspect of the disclosure, the retrieving portion is arranged in connection to the feeding portion and is adapted to guide the pickup lever arm past the first weld pin. The retrieving portion will secure that the pickup lever arm is displaced from the delivery position and pass the first weld pin in the magazine to the pickup position, so that the feeding portion can engage the next weld pin in the magazine.

According to another aspect of the disclosure, the pickup position is arranged at an interface between the pickup mechanism and the magazine. With this arrangement, the weld pins can be easily picked up from the magazine by the pickup lever arm.

According to another aspect of the disclosure, the pickup mechanism further comprises a trigger lever arm, which can be tilted between a start position and an end position. The trigger lever arm is interconnected with the pickup lever arm such that the trigger lever arm is displacing the pickup lever arm from the pickup position to the delivery position when the trigger lever arm is tilted from its start position to its end position, which provides an efficient and ergonomic handling of the welding gun.

According to another aspect of the disclosure, the pickup mechanism further comprises a fixed housing part and a movable housing part, where the fixed housing part is adapted to be attached to a cylinder of the welding gun and where the movable housing part is interconnected with the trigger lever arm such that the movable hosing part is displaced along a cylinder axis of the cylinder when the trigger lever arm is tilted from its start position to its end position. Through the movable housing part, the feeding of the weld pins can be made precise to secure an efficient feeding of the weld pins to the welding electrode.

The disclosure further concerns a system for welding, where the system comprises weld pins, a welding gun, a magazine, and a pickup mechanism as described above. The pickup mechanism is adapted for feeding the weld pins arranged in a stack of weld pins in the magazine from a pickup position in the magazine to a welding position at a welding electrode of the welding gun. These features of the welding system will make the handling of the welding gun faster and more convenient to the operator through a more efficient and precise feeding of the weld pins.

According to an aspect of the disclosure, the magazine comprises a weld pin track for receiving the stack of weld pins and a force feeding device adapted to exercise a feeding force on the stack of weld pins. The force feeding device will in an efficient way push the weld pins in the weld pin track to a position where they can be picked up by the pickup lever arm.

According to another aspect of the disclosure, the force feeding device comprises a spring, a pulley, and a pushing sleigh, wherein the pushing sleigh interacts with the spring over the pulley such that the pushing sleigh pushes the stack of weld pins towards a weld pin pickup opening of the magazine. This provides a simple and reliable construction with few parts involved.

According to a further aspect of the disclosure, the weld pins comprises a nail part attached to a sheet part, such that the weld pins have a flat side and a nail side. The sheet part comprises two essentially parallel guiding edges and a notch extending from a side edge of the sheet part in a direction towards the nail part, wherein the two guiding edges are arranged essentially parallel with the notch. The nail part is provided essentially in the centre of the sheet part and the notch stretches from a side edge and close to the centre of the sheet part, but normally not all the way in to the nail part. The notch and the parallel edges allow a stacking of the weld pins and smooth transportation of a stack of weld pins in a magazine with parallel walls.

According to another aspect of the disclosure, the width of the notch is smaller than the double diameter of the nail part. A narrower notch assures a straighter stacking of the weld pins due to less play between the edges of the notch and the nail part of the weld pin provided in the notch. It is therefore suggested that the width of the notch is at least slightly wider than the diameter of the nail part, and thus so wide that the nail part fits into the notch, and narrower than the double diameter of the nail part. Additional guiding means can thereby be avoided. According to another aspect of the disclosure, the weld pins are arranged in the stack of weld pins such that a nail part of a preceding weld pin extends through the notch of at least one succeeding weld pin in the stack of weld pins, and wherein a holding arrangement at least connects a first weld pin with a last weld pin in the stack of weld pins. This arrangement will realise a compact stack of weld pins.

According to a further aspect of the disclosure, the holding arrangement comprises a strip extending from the first weld pin to the last weld pin, or an adhesive connecting each of the weld pins in the stack with the neighbouring weld pin, or a track in which the stack of weld pins is inserted. Since the preceding weld pins nail extends through the notch of the succeeding weld pin, the weld pins is secured against rotational movements in the plane of the sheet part. Due to the holding arrangement connecting the weld pins, the stack of weld pins also becomes secured in an outwards direction of the notch.

The disclosure further concerns a method for feeding of weld pins with a pickup mechanism from a magazine to a welding electrode of a welding gun, where the pickup mechanism is attachable to the welding gun in connection to the welding electrode. The magazine is attachable to the pickup mechanism, wherein the pickup mechanism comprises a movable pickup lever arm displaceable between a pickup position and a delivery position. The method comprises the steps: displacing the weld pin from a pickup position in the magazine to a welding position at the welding electrode with the pickup lever arm, where the pickup lever arm has a pickup part comprising a feeding portion for feeding the weld pins from the pickup position to the welding position, and where the pickup part comprises a retrieving portion arranged with a sliding surface; displacing the pickup lever arm with the sliding surface in a direction essentially perpendicular to the direction of the movement between the delivery position and the pickup position when the sliding surface is in contact with a first weld pin in the magazine when the pickup lever arm moves between the delivery position and the pickup position to pick up the first weld pin, where the pickup part is configured such that the sliding surface bridges the first weld pin to the feeding portion at a predetermined position of the pickup lever arm such that the first weld pin engages the feeding portion in the pickup position.

BRIEF DESCRIPTION OF DRAWINGS The disclosure will be described in greater detail in the following, with reference to the attached drawings, in which

Fig. 1 a-c show schematically, different embodiments of a weld pin according to the disclosure,

Fig. 2a-d show schematically, different embodiments of a stack of weld pins according the disclosure,

Fig. 3 shows schematically, an embodiment of a welding system according to the disclosure,

Fig. 4a-b show schematically, a welding system with a pickup mechanism in a pickup position according to the disclosure, Fig. 5a-b show schematically, a welding system with a pickup mechanism in a position between a pickup position and a delivery position according to the disclosure,

Fig. 6a-b show schematically, a welding system with a pickup mechanism in a delivery position according to the disclosure, show schematically, a welding system with a pickup mechanism in a pickup position and a weld pin in a welding position according to the disclosure, shows schematically, an embodiment of a pickup lever arm according to the disclosure, shows schematically, an embodiment of a welding system with a weld pin magazine according to the disclosure, shows schematically, in a perspective view an embodiment of a welding system according to the disclosure. shows schematically, another embodiment of a welding system with a pickup mechanism in a pickup position according to the disclosure, shows schematically, another embodiment of a welding system with a pickup mechanism in a delivery position according to the disclosure, and shows schematically, another embodiment of a weld pin magazine according to the disclosure.

DESCRIPTION OF EXAMPLE EMBODIMENTS Various aspects of the disclosure will hereinafter be described in conjunction with the appended drawings to illustrate and not to limit the disclosure, wherein like designations denote like elements, and variations of the described aspects are not restricted to the specifically shown embodiments, but are applicable on other variations of the disclosure. All drawings are schematic. In the figures, relevant x-, y- and z-directions are indicated. Spatial references as upwards and downwards, above and below refers to how the features are positioned in the respective figures in relation to the respective coordinate system. Upwards is always in the positive y-direction and downwards is always in the negative y-direction, whereby above is always further away in the positive y-direction and below is further away in the negative y-direction in relation to the position referred to.

Figures 1 a-c schematically show different embodiments of a weld pin according to the disclosure. The weld pin 10 comprises a sheet part 1 1 and a nail part 12 attached to the sheet part 1 1 . The weld pin 10 may be constructed so that the nail part 12 is extending through or piercing the sheet part 1 1 essentially in the middle portion of the sheet part 1 1 . When the nail part 12 is attached to the sheet part 1 1 , the weld pin 10 has a flat side 16 and a nail side 17, whereby a tip 13 of the nail part 12 is arranged on the nail side 17. The nail part 12 may be attached to the sheet part 1 1 so that a nail head that may be arranged on the nail part 12 opposite the tip 13 is flush with the flat side 16 of the weld pin 10.

The nail part 12 is for example made of a homogeneous steel material. Other suitable materials for the nail part may be any material than can be welded. The sheet part 1 1 may for example be made of a sheet material, normally a durable and relatively inexpensive material such as a metal. Steel may be a suitable metal, and other materials, for example polymeric, paper or sandwich materials are also possible. The specification of the durability of the material of the sheet part can be different for different applications, whereby an application with shorter lifecycle might allow a lower grade material. The sheet material could also be made of a mesh material in order to reduce the amount material used and to save weight and material costs.

The sheet part 1 1 is provided with two guiding edges 15 and a notch 14, whereby the notch 14 extends in a direction essentially parallel with the two guiding edges 15, which also are arranged essentially parallel with each other. The notch 14 is in the embodiments shown in figures 1 a-c arranged in the middle between the two guiding edges 15. The width of the notch 14 may be chosen so that it is smaller than the double diameter of the nail part 12.

The two guiding edges 15 of the sheet part 1 1 are connected with two side edges 18, whereby the notch 14 is extending from one of the side edges 18. The two side edges 18 can be formed as continuous edges as shown in figure 1 b or be divided into edge segments as shown in figure 1 a. The shape and form of the two edges 18 is of subordinate significance, which is illustrated in figure 1 c, where the two edges 18 have been marked with dashed lines. The guiding edges 15 are adapted to interact with a track in a magazine 200 or a holding arrangement 1 10 for the weld pins 10, in order to keep a stack of weld pins 100 together in straight alignment during feeding of the stack of weld pins into the magazine 200.

Figure 1 a shows an embodiment of the weld pin 10 where each of the side edges 18 has been divided in to three equally long segments. The guiding edges 15 may also be designed so that they have the same length as the segments of the side edges 18, whereby the sheet part 1 1 has a symmetrical octagon-like shape, and where the notch 14 is extending from the middle segment of one of the side edges 18 of the octagon-like shaped sheet part 1 1 . As an alternative, the length of the guiding edges 15 may differ from the length of the segments of the side edges 18. Further, the segments of the side edges 18 may have different lengths if desired.

Figure 1 b shows an embodiment of the weld pin 10, which differs from the weld pin in figure 1 a in that the two side edges 18 are having a continuous circularlike or arc-like shape. The shape of the two side edges 18 may be any broken or continuous shape as long as the guiding edges 15 fulfil the requirements of being essentially parallel and essentially parallel with the notch 14, which is arranged essentially in the middle between the guiding edges 15. The flexibility in the form of the side edges 18 is illustrated in figure 1 c, where the side edge 18 is indicated with dashed lines. Figure 2a illustrates the stack of weld pins 100, where a number of weld pins 10 (10_1 , 10_2 ... 10_n) are arranged in a row to form the stack of weld pins 100. All weld pins 10 of the stack 100 are arranged with their nail part 12 oriented in the same direction. The stack 100 is formed so that the second weld pin 10_2 of the stack 100 is placed with its notch 14 surrounding the nail part 12 of the first weld pin 10_1 in the stack 100. As described above, the width of the notch 14 may be arranged so that it is smaller than the double diameter of the nail part 13, and in this way the weld pins 10 may be easily stacked upon each other. The weld pins 10 are thus arranged in the stack of weld pins 100 such that the nail part 13 of a preceding weld pin 10 extends through the notch 14 of at least one succeeding weld pin 10 in the stack of weld pins 100. The sheet part 1 1 of second weld pin 10_2 is thereby arranged above the sheet part 1 1 of the first weld pin 10_1 in the stack 100. The sheet part 1 1 of the third weld pin 10_3 is placed with its notch 14 surrounding the nail part 12 of the second weld pin 10_2 in the stack 100. The sheet part 1 1 of third weld pin 10_3 is thereby arranged upon the sheet part 1 1 of the second weld pin 10_2 in the stack 100. The succeeding weld pins 10_4 - 10_n are arranged correspondingly in relation to each other in the stack 100.

In figures 2b and 2c, the stack of weld pins 100 further comprises the holding arrangement 1 10 for holding the stack 100. The holding arrangement 1 10 secures that the weld pins are not becoming loose from the stack 100, when handling the stack of weld pins. In the embodiments shown in figures 2b-c, the holding arrangement 1 10 may be formed of a strip made of a suitable material. In the embodiment shown in figure 2b, the strip forming the holding arrangement 1 10 extends on the nail side 17 of the weld pins 10. In the embodiment shown in figure 2c the strip forming the holding arrangement 1 10 extends on the flat side 16 of the weld pins 10. The strip is attached to or connects at the least the first weld pin 10_1 and the last weld pin 10_n in the stack 100. For keeping the stack together in the stacking direction it is sufficient that the strip is attached only to the first weld pin 10_1 and the last weld pin 10_n in the stack. By providing the strip over and/or under the sheet part 1 1 , the stack of weld pins 100 is supported in the direction of the holding arrangement 1 10. The strip or string can be rigid in order to better hold the stack in a straight line, horizontally and vertically.

In an alternative embodiment, the strip may be attached to more than two weld pins 10 in the stack 100, such as for example every second weld pin 10 in the stack 100 or even all weld pins 10 in the stack 100.

Independently of how many weld pins 10 the strip is attached to, the strip can be arranged on the nail side 17 of the weld pins 10 or on the flat side 16 of the weld pins 10. When the strip is arranged on the nail side 17, the strip can be arranged on either side of the nails parts 12, as indicated in figure 2b where the strip is arranged on one side of the nail parts 12, or as an alternative double sided on both sides of the nail parts 12 of the weld pins, and be attached to the nail parts 12 and/or the sheet parts 1 1 . Two or more strips may also be used if desired. The strip may be designed so that it is rigid enough to carry the weight of the stack 100 without collapsing. Suitable materials for the holding arrangement

1 10 may for example be a strip of plastic material, or a strip made of paper polymer, textile, metal or glue like material. Other suitable materials are also possible to use. The holding arrangement 1 10 may be attached to the stack of weld pins 100 with suitable glues or other adhesive materials, which may be integrated in the strip. In this way the strip may be designed to connect the first and last weld pin, more than two weld pins, every second weld pin or for example all weld pins in the stack.

In figure 2d an alternative embodiment of the holding arrangement 1 10 is shown, where the holding arrangement 1 10 is formed as an elongated track

1 1 1 made of a suitable material. The elongated track 1 1 1 is formed with a u- shaped cross-sectional shape, with a bottom wall 1 12 and two side walls 1 13. The distance between the side walls 1 13 corresponds to the distance between the guiding edges 15 of a weld pin 10, such that when the weld pin 10 is arranged with its flat side 16 on the bottom of the track 1 1 1 , the guiding edges 15 are arranged essentially parallel with the side walls 1 13 of the track 1 1 1 . The sheet part 1 1 may be held in the track 1 1 1 by frictional forces between the guiding edges 15 and the side walls 1 13. As an alternative, one or both of the side walls 1 13 may be provided with an elongated longitudinal groove or similar arrangement, which is arranged to receive the guiding edges 15 of the sheet parts 1 1 of the weld pins 10. The distance between the side walls 1 13 can then be made narrower than the distance between the two essentially parallel guiding edges 15 of the weld pins 10, whereby at least one of the side walls 1 13 is provided with the elongated groove or similar arrangement, extending essentially parallel with the bottom wall 1 12 of the track 1 1 1 . If the track 1 1 1 is arranged with one elongated groove, one of the guiding edges 15 of the weld pins are guided by the groove and the other guiding edge is arranged in connection to the opposite side wall 1 13 of the track 1 1 1 . If both side walls are arranged with elongated grooves, both guiding edges 15 of the weld pins 10 are guided by the elongated grooves.

The track 1 1 1 may be adapted to be inserted into the magazine 200, whereby the magazine 200 is arranged for feeding the weld pins 10 arranged in the track 1 1 1 when the welding gun is operated. The holding arrangement 1 10 in this embodiment thus comprises the track 1 1 1 in which the stack of weld pins 100 is inserted. The track 1 1 1 can be provided with a release mechanism at each of its ends, enabling a securing and releasing of the weld pins in the stack of weld pins.

The purpose of the holding arrangement 1 10, independently of how it is formed, is as described above to keep the stack 100 together so that it does not fall apart to individual weld pins 10 during handling and transportation of the stack 100. The holding arrangements 1 10 may further facilitate easy insertion of a stack 100 into the magazine 200. As an alternative, the holding arrangement 1 10 may be made of an adhesive material connecting each of the weld pins 10 in the stack 100 with the neighbouring weld pin 10.

In figure 3, a welding system 500 is disclosed in an exploded view, where the welding system 500 comprises a stud welding gun 400, a pickup mechanism 300, and the magazine 200 provided with a stack of weld pins 100. Each of the components of the welding system will be further described below. The pickup mechanism 300 is adapted for individually feeding the weld pins 10 arranged in the stack of weld pins 100 in the magazine 200 from a pickup position in the magazine 200 to a welding position at a welding electrode 401 of the welding gun 400.

The stud welding gun 400 may be of any conventional type, such as for example a standard welding gun for welding of studs and/or weld pins. The stud welding gun 400 comprises a housing 407 provided with a handle 402 and a cylinder 403. The stud welding gun has a rear part 408, where the handle 402 is provided, and a front part 409, where the outer part of the cylinder 403 is arranged, as shown in figure 3. The cylinder 403 has a rotational axis 404, which also defines a welding axis, when the nail part 12 of the weld pin 10 is arranged essentially coaxially with the cylinder axis 404. An electric power supply cable 406 is provided at the end of the handle 402 for supplying power to the stud welding gun 400. Inside the housing 407, the stud welding gun 400 is equipped with components required for supplying power to the welding electrode 401 , which is arranged at the tip or front end of the cylinder 403. At the tip of the cylinder 403, one or more permanent magnets are also arranged, which permanent magnets can hold weld pins 10 when placed thereon. In this way, the weld pins can be attached to the tip of the cylinder 403 with the magnetic force generated by the permanent magnet, as shown in figure 7b. The cylinder 403 has normally a circular cross-sectional shape. However, the cylinder 403 may have other cross-sectional shapes, such as for example elliptical, quadratic, or hexagonal. A welding trigger 405 is arranged on the front side of the handle 402. By actuating the welding trigger 405, a welding cycle is initiated. In a normal handling of the stud welding gun 400, the welding trigger 405 is actuated by an index finger of an operator's hand holding the stud welding gun 400. The welding gun 400 may also be custom made instead of using a standard welding gun existing on the open market. By making a custom made welding gun it is possible to use electromagnets instead of permanent magnets.

The pickup mechanism 300 is as shown in figures 3, 4b, 5b and 6b provided with a fixed housing part 301 and a movable housing part 302. The pickup mechanism 300, with the fixed housing part 301 and the movable housing part 302, is adapted to being attached to the cylinder 403 of the welding gun 400 in connection to the welding electrode 401 , where the fixed housing part 301 is provided to be securely attached to the cylinder 403 with suitable fixation means. In the embodiment shown, the fixed housing part 301 is attached to the cylinder 403 through an attachment screw 303, which tightens a clamp ring 304 arranged on the pickup mechanism 300 around the cylinder 403.

The pickup mechanism 300 is provided with a trigger lever arm 320, which can be tilted between a start position, as shown in figure 4b, and an end position, as shown in figure 6b. In the embodiments shown in the figures, the trigger lever arm 320 is arranged so that it can be manually actuated or tilted by the operator's finger. However, it may as an alternative also be possible to design the pickup mechanism 300 so that it is not manually operated, but instead electrically or pneumatically operated. The trigger lever arm 320 is interconnected with a pickup lever arm 310 such that the trigger lever arm 320 is displacing the pickup lever arm 310 from a pickup position, as shown in figures 4a and 4b, to a delivery position, as shown in figures 6a and 6b. When the pickup lever arm 310 is in the pickup position, the pickup lever arm 310 is ready to pick up a first weld pin 10_1 from the magazine 200. The first weld pin 10_1 in the magazine 200, as shown in figure 4b, is in a pickup position ready to be fed from the magazine 200 to the welding electrode 401. When the pickup lever arm 310 is in the delivery position, the weld pin 10 can be delivered to the welding electrode 401 in a welding position. The welding position of the weld pin 10 is shown in figure 7b. The pickup lever arm 310 is thus displaceable between the pickup position and the delivery position, and is adapted for displacing the weld pin 10 from the pickup position in the magazine 200 to the welding position at the welding electrode 401 . As shown in figure 4b, the pickup position is arranged at an interface between the pickup mechanism 300 and the magazine 200.

When the pickup mechanism 300 is attached to the welding gun it may be arranged in any angle in relation to the cylinder 403 of the welding gun 400. It is thus possible to rotate the pickup mechanism around the cylinder axis 404 of the cylinder 403, or arrange the pickup mechanism in any desired angle of rotation in relation to the cylinder axis 404, before tightening of the attachment screw 303. This possibility of positioning the pickup mechanism in relation to the cylinder may especially be useful when using the welding gun 400 with the pickup mechanism 300 in tight spaces, since a turning of the pickup mechanism 300 in relation to the welding gun 400 might facilitate an easier access to a welding point in the tight space. The embodiments shown in the figures will describe a pickup mechanism 300 arranged in alignment with the handle 402 of the welding gun 400, i.e. the trigger lever arm 320 will be arranged in a plane parallel with a plane of the handle 402 of the welding gun 400. In the figures, the trigger lever arm 320 will thus point downwards in the same direction as the handle 402, as shown in a perspective view in figure 10.

As shown in figures 4b and 6b, the movable housing part 302 is arranged in relation to the fixed housing part 301 so that it can slide in the axial direction of the cylinder 403 between an inner position, when the pickup lever arm 310 is in the pickup position, and an outer position, when the pickup lever arm 310 is in the delivery position. The movable housing part 302 may be constructed as a separate structure arranged on the outside of the fixed housing part 301 . The movable housing part 302 is interconnected with the trigger lever arm 320 such that the movable hosing part 302 is displaced along the cylinder axis 404 of the cylinder 403 when the trigger lever arm 320 is tilted from its start position to its end position. In figure 4b the movable housing part 302 is in the inner position, and in figure 6b the movable housing part 302 is in the outer position. A number of interconnected lever arms, as shown more in detail in the figures, are connecting the fixed housing part 301 and the movable housing part 302. As indicated in figure 9, the interconnecting lever arms are symmetrically arranged on both sides of the pickup mechanism 300. A pickup lever arm 310 is connected to the movable housing part 302 at a first rotational axis 31 1 , and arranged so that the pickup lever arm 310 can tilt around the first rotational axis 31 1 . The pickup lever arm 310 is connected to the first rotational axis 31 1 in a position between its front end and rear end. A first lever arm 324 is connected to the fixed housing part 301 at its rear end so that it can rotate around a second rotational axis 325. The front end of the first lever arm 324 and the rear end of the pickup lever arm 310 are rotatably connected to a third rotational axis 326. In this way, the first lever arm 324 and the pickup lever arm 310 can rotate in relation to each other around the third rotational axis 326. When the movable housing part 302 is in its inner position, as shown in figure 4b, the first lever arm 324 is angled in a direction downwards from the third rotational axis 326 towards the second rotational axis 325, and the pickup lever arm 310 is angled in a direction downwards from the third rotational axis 326 towards the first rotational axis 31 1 . In this position, corresponding to the pickup position, the rear end of the pickup lever arm 310 and the front end of the first lever arm 324 are located in a position, which is higher than the positions of the front end of the pickup lever arm 310 and the rear end of the first lever arm 324 respectively.

The trigger lever arm 320 is at its upper end attached to the movable housing part 301 at a fourth rotational axis 321 , so that the trigger lever arm 320 can tilt around the fourth rotational axis 321 . The trigger lever arm 320 is at the fourth rotational axis 321 connected to a rear end of a first intermediate lever 322. Both the trigger lever arm 320 and the first intermediate lever 322 are fixedly attached to a rotating shaft, which can rotate around the fourth rotational axis. In this way, the first intermediate lever 322 is arranged in relation to the trigger lever arm 320 so that the first intermediate lever 322 rotates with the trigger lever arm 320 around the fourth rotational axis 321 , when the trigger lever arm 320 is tilted. The first intermediate lever 322 is further in its front end connected to a lower end of a second intermediate lever 323 at a fifth rotational axis 327. The upper end of the second intermediate lever 323 is connected to the third rotational axis 326, and as shown in the figures, the second intermediate lever 323 is arranged essentially in an upwards-downwards direction.

When actuating the trigger lever arm 320 from its start position, as shown in figures 4a and 4b, to its end position, as shown in figures 6a and 6b, the first intermediate lever 322 turns about the fourth rotational axis 321 and thereby pulls the second intermediate lever 323 in a direction downwards. The downwards movement of the second intermediate lever 323 causes a downwards movement of the front end of the first lever arm 324 and the rear end of the pickup lever arm 310 respectively, whereby they rotate around the second rotational axis 325 and the first rotational axis 31 1 respectively. The downward directed angle of the first lever arm 324 and the pickup lever arm 310, as described above, in combination with the downwards movement of the front end of the first lever arm 324 and the rear end of the pickup lever arm 310 respectively, will press the movable housing part 302 from its inner position to its outer position, simultaneously as the pickup lever arm 310 is displaced between its pickup position and its delivery position. In figures 5a and 5b, a position of the pickup lever arm 310 between the pickup position and the delivery position is shown for better understanding of the function of the pickup mechanism 300. The movable housing part 302 may be arranged with a lower stop pin 341 and an upper stop pin 342 on one or both sides of the movable housing part, where the stop pins delimit the movement of the pickup lever arm 310. The lower stop pin 341 and the upper stop pin 342 may be of any suitable construction, such as for example metal pins attached to the movable housing part 302.

The pickup lever arm 310 is thus displaced from the pickup position to the delivery position when the pickup lever arm 310 is tilted in a first rotational direction around a first rotational axis 31 1 , and the pickup lever arm 310 is displaced from the delivery position to the pickup position when the pickup lever arm 310 is tilted in a second rotational direction around the first rotational axis 31 1 . The second rotational direction is opposite the first rotational direction. In the figures, the pickup mechanism 300 is arranged at the welding gun 400 such that the trigger lever arm 320 is aligned with the handle 402 of the welding gun 400. The trigger lever arm 320 is thereby centrally arranged on the pickup mechanism 300, as shown in figure 9. The pickup mechanism 300 is provided with a double sided set of interconnected lever arms 310, 322, 323, 324 actuated by the same centrally arranged trigger lever arm 320. In an alternative embodiment, the pickup mechanism 300 may be provided with a single set of interconnected lever arms arranged on only one of the sides of the pickup mechanism. Further, the trigger lever arm 320 may as an alternative be arranged so that it is not centrally arranged, such that it is not located directly in front of the welding trigger 405 of the welding gun 400.

The movable housing part 302 or the interconnected lever arms 301 , 322, 323, 324 may be subjected to a spring force acting in a way such that the movable housing part 302 is in its inner position and thereby the pickup lever arm 310 in its pickup position when there is no external actuating force applied to the trigger lever arm 320.

The pickup mechanism 300 is provided with a feeding surface 330 provided in-between the pickup position and the delivery position of the pickup lever arm 310. One or more magnets may be arranged in relation to the feeding surface 330 so that magnetic forces act on the weld pins 10 when they are passing the feeding surface 330. For example can permanent magnets be used; alternatively can electro magnets be used. The weld pins 10 may then be in direct contact with the feeding surface 330 during the whole movement of the weld pin 10 from the pickup position in the magazine 200 to the welding position at the welding electrode 401 , independently of how gravity is acting on the weld pins 10.

In figures 5a and 5b, the weld pin 10 is shown when it passes over the feeding surface 330. As the feeding surface 330 is arranged on the movable housing part 302, the feeding surface 330 will be aligned with the welding electrode 401 when the pickup lever arm 310 reaches the delivery position, as shown in figure 6b. Due to the magnetic forces from the permanent magnet at the feeding surface 330, the weld pin 10 that is fed from the pickup position to the welding position will be kept at the feeding surface 330 independently of the spatial position of the pickup mechanism 300 in the room. When the weld pin 10 is in its welding position, the permanent magnet at the welding electrode 401 will hold the weld pin 10 correctly positioned during the welding operation.

The pickup mechanism 300 may be provided with a spring arrangement acting upon one of the interconnected lever arms 310, 322, 323, 324, the trigger lever arm 320 and/or the movable housing part 302 to keep or restore the pickup lever arm 310 to its pickup position from the delivery position.

The pickup lever arm 310 is at the front end provided with a pickup part 312 arranged in a direction essentially perpendicular to the pickup lever arm 310, as shown more in detail in figures 8 and 9. In the embodiments shown in the figures, the pickup mechanism 300 is provided with double sets of interconnecting pickup lever arms 310, where each of the pickup lever arms 310 is provided with a pickup part 312.

The pickup parts 312 are each arranged with a feeding portion 314 and a retrieving portion 313 provided at the pickup parts 312 of the pickup lever arms 310. The feeding portion 314 is arranged for transporting or feeding the weld pin 10 from the pickup position in the magazine 200 to the welding position at the welding electrode 401 . The retrieving portion 313 is arranged with a sliding surface 315 for displacing the pickup lever arm 310 in a direction essentially perpendicular to the direction of the movement between the delivery position and the pickup position when the sliding surface 315 is in contact with a first weld pin 10_1 in the pickup position in the magazine 200, and when the pickup lever arm 310 moves between the delivery position and the pickup position to pick up the first weld pin 10_1. The displacement of the pickup lever arms 310 in the direction essentially perpendicular to the direction of the movement between the delivery position and the pickup position may for example be achieved through a flexible suspension of the pickup lever arms 310, a spring loaded suspension or through using a flexible material in the pickup lever arms 310. The flexibility in the construction of the pickup lever arms 310 will allow that the pickup lever arms 310 are flexing a short distance outwards in the direction essentially perpendicular to the direction of the movement between the delivery position and the pickup position.

An exemplary embodiment of the feeding portion 314 and the retrieving portion 313 are disclosed in figure 8. The feeding portion 314 is shaped such that it grasps around the weld pin 10 and enables a lifting of the weld pin 10 from the pickup position to the welding position via the feeding surface 330. The feeding portion 314 may have an arc-formed concave shape, as shown in figure 8, which when the pickup part 312 is arranged in the pickup position is adapted to engage the first weld pin 10_1 such that the first weld pin 10_1 can be lifted by the feeding portion 314 from the pickup position to the welding position. The feeding portion 314 may also be designed with other suitable shapes than the arc-formed concave shape described. When the pickup mechanism 300 is provided with double pickup parts 312, a relatively flat feeding portion 314 can be used, since the weld pins 10 are held in position between the two feeding portions 314 when fed from the pickup position to the welding position. As shown in figure 8, the two nail pickup profiles are forming a V-shaped feeding arrangement for the weld pins 10. If the pickup mechanism 300 is provided with just one pickup lever arm 310, the feeding portion 314 may be more hook- shaped in order to achieve a sufficient lifting force on the weld pin 10.

The pickup part 312 is configured such that the sliding surface 315 bridges the first weld pin 10_1 to the feeding portion 314 at a predetermined position of the pickup lever arm 310, and such that the feeding portion 314 engages the first weld pin 10_1 in the pickup position. The retrieving portion 313 with the sliding surface 315 is arranged in connection to the feeding portion 314 and is adapted to guide the pickup lever arm 310 past the first weld pin 10_1 .

The retrieving profile 313 is thus shaped with the sliding surface 315 such that when the pickup lever arm 310 is displaced from its delivery position to its pickup position and passing the first weld pin 10_1 arranged in the pickup position in the magazine 200, the pickup parts 312 of the pickup lever arms 310 are guided past the first weld pin 10_1 due to the shape of the sliding surface 315. The sliding surface 315 may thereby be provided with a suitable convex shape or a flat surface inclining outwards, as shown in figure 8. When the pickup parts 312 are passing the weld pin 10, they are pressed slightly outwards in a direction away from the weld pin 10 so that they can pass the weld pin 10. A gap is formed between the respective pickup parts 312, between the feeding portion 314 and the retrieving portion 313, in which gap the nail pin 10 can pass through when the pickup lever arm 310 is displaced from the delivery position to the pickup position.

Figure 3 discloses an embodiment of the magazine 200 adapted to be attached to the pickup mechanism 300. The first weld pin 10_1 in the stack of weld pins 100 arranged in the magazine 200 is provided at the pickup position of the pickup lever arm 310, when the magazine is attached to the pickup mechanism 300, as shown in figure 4b. The magazine 200 has an elongated shape, which is adapted to hold the stack of weld pins 100. The first pin 10_1 of the stack of weld pins 100 is arranged at a front end 230 of the magazine 200, and the magazine has a rear end 231 opposite the front end 230. The front part of the pickup mechanism 300 is arranged with an attachment portion 331 for holding the magazine 200. The attachment portion 331 is as shown in figure 9 arranged below the feeding surface 330, and the magazine 200 can be inserted into the attachment portion 331 , as indicated with the arrow in figure 9. The attachment portion 331 may comprise one or more steering pins 340 or other suitable means for holding the magazine 200 in position in relation to the pickup mechanism 300. The steering pins 340 may be of any suitable construction, such as for example metal pins attached to the movable housing part 302. The attachment portion 331 may further comprise a spring loaded locking member 343 that locks the magazine 200 in position in relation to the pickup mechanism 300. The locking member 343 may be of any suitable construction, such as for example a spring loaded pin or ball, which is interacting with a recess provided in the magazine 200.

As shown in figure 3, the magazine 200 comprises a weld pin track 210, which is adapted to receive the stack of weld pins 100. The stack of weld pins 100 may be inserted into the weld pin track 210 together with its holding arrangement 1 10, whereby the insert action enables a release of the first weld pin 10_1 in the stack of weld pins 100 from the rest of the weld pins 10. The release of at least the first weld pin 10_1 can also be performed manually. The holding arrangement 1 10 can also be completely removed manually.

The weld pin track 210 may extend along essentially the full length of the magazine 200. The magazine 200 further comprises a force feeding device adapted to exercise a feeding force on the stack of weld pins 100. In the embodiment shown in figure 3, the force feeding device comprises a spring 220, a pulley 221 , and a pushing sleigh 222. The spring 220 is at one end connected to the rear end 231 of the magazine 200 and the other end of the spring 220 is connected to a string 223 or other suitable means. The string 223 runs from the spring 220 over the pulley 221 , which is arranged in the front end 230 of the magazine 200, and to the pushing sleigh 222. The string 223 is thus at one end attached to the spring 220 and at the other end to the pushing sleigh 222, as shown in figure 3. The pushing sleigh 222 interacts with the spring 220 over the pulley 221 through the string 223 such that the pushing sleigh 222 pushes the stack of weld pins 100 towards a weld pin pickup opening 201 of the magazine 200, as shown in figure 13. As shown in figure 3, the string 223 runs above the stack of weld pins 100 to the pushing sleigh 222 so that the movement of the stack of weld pins 100 is not disturbed by the string 223. The pushing sleigh 222 may be arranged in the magazine in a suitable way so that it can slide freely in the weld pin track 210. The spring 220 is arranged in a spring compartment 224 provided parallel with the weld pin track 210. The spring compartment 224 is arranged above the weld pin track 210, in the position of the magazine 200 shown in figure 3, such that essentially the full length of the magazine 200 can be stacked with weld pins 10 when fully loaded. The string 223 is as described above attached to the spring 220, and the string 223 is running inside the spring compartment 224 to the pulley 221 arranged at the upper end of the magazine 200. The string is redirected in the opposite direction via the pulley 221 and extends further into the weld pin track 210 so that the second end of the string 223 is attached to the pushing sleigh 222. The pushing sleigh 222 is arranged to push the stack of weld pins 100 in a direction towards the upper end of the magazine 200, in the position shown in figure 3, so that the first weld pin 10_1 of the stack of weld pins 100 can be arranged in a pickup position. When the magazine 200 is loaded with the stack of weld pins 100, the string 223 and the pushing sleigh 222 are pulled further into the magazine 200, such that the spring 220 is tensioned. The string 223 is placed in the upper part of the weld pin track 210, when the magazine 200 has the position shown in figure 3, and when the stack of weld pins 100 is inserted into the magazine 200 from the bottom, the pushing sleigh 222 is positioned below the last weld pin 10_n in the stack of weld pins 100. The pushing sleigh 222 thereby exercises a feeding force on the stack of weld pins 100, so that when the first pin 10_1 in the stack 100 is picked up by the pickup mechanism 300, the next pin 10_2 is pushed into the pickup position. As schematically shown in figure 13, the weld pin track 210 may be provided with an elevation 21 1 that will position the second weld pin 10_2 in the stack of weld pins 100 in a position, where its sheet part does not rest upon the first weld pins 10_1 sheet part, the front part of the second weld pin 10_2 is thereby lifted so that it is not impacting the first weld pin 10_1 in its pickup position. The elevation 21 1 may be provided with a sloping surface facing the stack of weld pins 100, which sloping surface lifts the second weld pin 10_2 into the desired position when the stack of weld pins 100 is pushed in a direction towards the pickup opening 201 in the magazine 200. The elevation 21 1 may be made of any suitable material, such as for example metal, and is extending across the weld pin track 210 essentially perpendicular to the feeding direction of the stack of weld pins. The elevation 21 1 may additional have an exemplary function of positioning the rear part of the first weld pin 10_1 in order for the first weld pin 10_1 to receive a correct orientation in the pickup position. The elevation 21 1 may for example take the form of an elongated ridge, a more circular ball segment or be divided into several small elevation segments of suitable type.

As shown in figures 3, 6a, 6b and 13, the magazine 200 may be arranged with holding edges 212 for holding the stack of weld pins 100 in position in the magazine 200. The holding edges 212 may be arranged at the front end 230 of the magazine 200 on each side of the stack of weld pins 100 so that the front edge of the second weld pin 10_2 is resting against the holding edges 212. There is a gap 213 arranged between the holding edges 212 so that the nail part 12 of the weld pins 10 can pass in the gap 213, and the holding edges 212 may, as shown in figure 13, be slightly inclined in a direction towards the stack of weld pins 100 in the magazine 200 to better hold the stack of weld pins 100 in position. When the first weld pin 10_1 is removed from the magazine 200, the second weld pin 10_2 can through interaction with the pushing sleigh 222, the inclined holding edges 212, and the elevation 21 1 slide forward in the magazine 200, with the sheet part 1 1 below the holding edges 212 at the weld pin pickup opening 201 and the nail part 12 in the gap 213, when the magazine is positioned as shown in figure 13. In this way, when the first weld pin 10_1 is picked up from the magazine 200 with the pickup mechanism 300, the second weld pin 10_2 will move forward in the magazine 200 through the pushing action from the pushing sleigh 222 and then become the first weld pin 10_1 in the stack of weld pins 100. The inclined holding edges 212 may be shaped to match the shape of the sheet part 1 1 of the weld pins 10 for a secure holding of the weld pins 10 in the magazine 200.

The magazine may be provided with a groove 225 or other suitable means for holding the magazine 200 in position in relation to the pickup mechanism 300. The groove 225 may be arranged in each side wall of the magazine, as schematically shown in figure 9, so that the grooves 225 can interact with the steering pins 340 arranged in the front part of the pickup mechanism 300. If desired, one or more front steering pins 344 may be arranged in the front part of the pickup mechanism, as shown in figure 9, for example in a position aligned with the length direction of the magazine 200. The front steering pins secure that the magazine 200 is prevented from rotating about the steering pins 340. The magazine 200 may further be provided with a recess or similar means for locking the magazine 200 in position in relation to the pickup mechanism 300. The recess is arranged to interact with the spring loaded locking member 343 provided on the pickup mechanism 300.

The function of the welding system 500 and especially the pickup mechanism 300 will be further described below. In figures 4a and 4b, the welding system 500 with the weld pin in a pickup position is shown. As described above, the welding system 500 comprises the welding gun 400, the pickup mechanism 300 and the magazine 200. The magazine 200 is loaded with the stack of weld pins 100 and is attached to the pickup mechanism 300. The pickup mechanism 300 is in the pickup position, where the first weld pin 10_1 in the stack of weld pins 100 may be fed to the welding electrode 401 in the welding position.

By pressing the trigger lever arm 320 the actuation force will, via the interconnected lever arms 310, 322, 323, 324 and the pickup part 312, lift the weld pin 10_1 from its pickup position in the magazine 200 via the feeding surface 330 to the welding position shown in figures 7a and 7b at the welding electrode 401 . In figures 5a and 5b, the welding system is shown with the pickup lever arm 310 in a position between the pickup position and the delivery position, where the weld pin 10 is fed to the welding electrode 401 via the feeding surface 330. At the welding electrode 401 the weld pin 10 is held in position for welding by the one or more permanent magnets. As described above, the pickup lever arm 310 is displaced simultaneously with the movable housing part 302 of the pickup mechanism 300, so that the movable housing part 302 is displaced from its inner position, as shown in figure 4b, to its outer position, as shown in figure 6b. When the weld pin 10 is displaced to the welding position, the pickup lever arm 310 is displaced back from the delivery position to the pickup position so that a new weld pin 10 is ready to be picked up by the pickup lever arm 310, as shown in figures 7a and 7b. The magazine 200 is attached to the movable housing part 302 of the pickup mechanism 300. When the movable housing part 302 and the pickup lever arm 310 are in the inner position, as shown in figure 4b, the whole magazine 200 is in a more retracted position than when the movable housing part 302 and the pickup lever arm 310 is in the delivery position, as shown in figure 6b. In this way, the weld pins 10 in the magazine 200 do not interfere when the welding gun 400 is being operated.

An alternative embodiment of an actuating mechanism of the pickup mechanism 300 is schematically shown in figures 1 1 and 12. The pickup mechanism 300 is in this embodiment provided with a trigger lever arm 320, which can be displaced between a start position, as shown in figure 1 1 , and an end position, as shown in figure 12. When the trigger lever arm 320 is displaced from the start position to the end position, a pickup lever arm 310 with a pickup part 312 is displaced from a pickup position, as shown in figure 1 1 , to a delivery position, as shown in figure 12. The pickup lever arm 310 with the pickup part 312 is provided with a feeding portion 314 arranged at the front end of the pickup lever arm 310, in the same way as described in the earlier embodiments in relation to figure 8, and the feeding portion 314 is designed to transport a weld pin 10 from the pickup position to the welding position. The pickup lever arm 310 may thus in this embodiment be of the same construction and design as described in the earlier embodiments above.

The pickup lever arm 310 and a first lever arm 324 are connecting a fixed housing part 301 and a movable housing part 302 of the pickup mechanism. The movable housing part 302 is arranged in relation to the fixed housing part 301 so that it can slide between an inner position and an outer position in the axial direction of the cylinder 403, when the pickup mechanism 300 is mounted on the welding gun 400. The interconnecting lever arms may be symmetrically arranged on both sides of the pickup mechanism 300, or as an alternative arranged on only one of the sides of the pickup mechanism 300. The pickup lever arm 310 is connected to the movable housing part 302 at a first rotational axis 31 1 , and arranged so that the pickup lever arm 310 can tilt around the first rotational axis 31 1 . The pickup lever arm 310 is connected to the first rotational axis 31 1 in a position between its front end and rear end. The first lever arm 324 is connected to the fixed housing part 301 at its rear end so that it can rotate around a second rotational axis 325. The front end of the first lever arm 324 and the rear end of the pickup lever arm 310 are rotatably connected to a third rotational axis 326. In this way, the first lever arm 324 and the pickup lever arm 310 can rotate in relation to each other around the third rotational axis 326. When the movable housing part 302 is in its inner position, as shown in figure 1 1 , the first lever arm 324 is angled in a direction downwards from the third rotational axis 326 towards the second rotational axis 325, and the pickup lever arm 310 is angled in a direction downwards from the third rotational axis 326 towards the first rotational axis 31 1 . In this position, corresponding to the pickup position, the rear end of the pickup lever arm 310 and the front end of the first lever arm 324 are located in a position, which is higher than the positions of the front end of the pickup lever arm 310 and the rear end of the first lever arm 324 respectively. The trigger lever arm 320 is at its upper end attached to a lever arm bracket 328 attached to the first lever arm 324, so that the trigger lever arm 320 is rotatably displacing or tilting the first lever arm 324 around the second rotational axis 325 when being actuated. When actuating the trigger lever arm 320 from its start position, as shown in figure 1 1 , to its end position, as shown in figure 12, the first lever 324 turns about the second rotational axis 325 and thereby pulls the third rotational axis 326 in a direction downwards, causing a downwards movement of the front end of the first lever arm 324 and the rear end of the pickup lever arm 310 respectively, whereby they rotate around the second rotational axis 325 and the first rotational axis 31 1 respectively. The downward directed angle of the first lever arm 324 and the pickup lever arm 310, as described above, in combination with the downwards movement of the front end of the first lever arm 324 and the rear end of the pickup lever arm 310 respectively, will press the movable housing part 302 from its inner position to its outer position, simultaneously as the pickup lever arm 310 is displaced between its pickup position and its delivery position.

Also in this embodiment, the pickup mechanism 300 may be arranged in any angle in relation to the cylinder 403 of the welding gun 400. It is thus possible to rotate the pickup mechanism around the cylinder axis 404 of the cylinder 403, or arrange the pickup mechanism in any desired angle of rotation in relation to the cylinder axis 404.

The pickup mechanism 300 may be provided with a double sided set of pickup lever arms 310 and first lever arms 324 actuated by the same centrally arranged trigger lever arm 320. The lever arm bracket 328 may for example be U-shaped, or have another suitable shape, and is connected to the first lever arms 324 with suitable fastening means. The lever arm bracket 328 is extending in a direction downwards from the first lever arms 324 and below the movable housing part 302, when the pickup mechanism 300 is mounted to the welding gun 400 in the position shown in figures 1 1 and 12. As described above, the pickup mechanism 300 may be provided with a single set of interconnected lever arms arranged on only one of the sides of the pickup mechanism. The lever arm bracket 328 may in this embodiment for example be L-shaped and is connected to the first lever arm 324. The lever arm bracket 328 may also be designed with other suitable shapes. The lever arm bracket 328 is extending in a direction downwards from the first lever arm 324 and below the movable housing part 302, when the pickup mechanism 300 is mounted to the welding gun 400 in the position shown in figures 1 1 and 12. The movable housing part 302 may be subjected to a spring force acting in a way such that the movable housing part 302 is in its inner position and thereby the pickup lever arm 310 in its pickup position when there is no external actuating force applied to the trigger lever arm 320.

The pickup mechanism 300 may be provided with a spring arrangement acting upon one of the pickup lever arm 310, the first lever arm 324, the trigger lever arm 320 and/or the movable housing part 302 to keep or restore the pickup lever arm 310 to its pickup position from the delivery position.

It will be appreciated that the above description is merely exemplary in nature and is not intended to limit the present disclosure, its application or uses. While specific examples have been described in the specification and illustrated in the drawings, it will be understood by those of ordinary skill in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the present disclosure as defined in the claims. Furthermore, modifications may be made to adapt a particular situation or material to the teachings of the present disclosure without departing from the essential scope thereof. Therefore, it is intended that the present disclosure not be limited to the particular examples illustrated by the drawings and described in the specification as the best mode presently contemplated for carrying out the teachings of the present disclosure, but that the scope of the present disclosure will include any embodiments falling within the foregoing description and the appended claims. Reference signs mentioned in the claims should not be seen as limiting the extent of the matter protected by the claims, and their sole function is to make claims easier to understand.

REFERENCE SIGNS

10: Weld pin

11: Sheet part

12: Nail part

13: Nail tip

14: Notch

15: Guiding edges

16: Flat side

17: Nail side

18: Side edges

100: Stack of weld pins

110: Holding arrangement

111: Track

112: Bottom wall

113: Side walls

200: Magazine

201: Weld pin pickup opening

210: Weld pin track

211: Elevation

212: Holding edge

213: Gap

220: Spring

221: Pulley

222: Pushing sleigh

223: String

224: Spring compartment

225: Groove

230: Front end

231: Rear end

300: Pickup mechanism

301: Fixed housing part 302: Movable housing part

303: Attachment screw

304: Clamp ring

310: Pickup lever arm

31 1 : First rotational axis

312: Pickup part

313: Retrieving portion

314: Feeding portion

315: Sliding surface

320: Trigger lever arm

321 : Fourth rotational axis

322: First intermediate lever

323: Second intermediate lever

324: First lever arm

325: Second rotational axis

326: Third rotational axis

327: Fifth rotational axis

328: Lever arm bracket

330: Feeding surface

340: Steering pin

341 : Lower stop pin

342: Upper stop pin

343: Locking member

344: Front steering pins

400: Welding gun

401 : Welding electrode

402: Handle

403: Cylinder

404: Cylinder axis

405: Welding trigger

406: Electric power supply cable

407: Housing 408: Front part

409: Rear part

500: Welding system