CN107887463A - A kind of pre-splicing frame component pressurizing unit of photovoltaic - Google Patents

Abstract

The invention discloses a kind of pre-splicing frame component pressurizing unit of photovoltaic, including pedestal, two pairs of extrusion arms being arranged on pedestal, any to be provided with a fixed press arm and a movable extrusion arm to extrusion arm, the movable extrusion arm in two pairs of extrusion arms passes through the fit linkage of transmission group.Under the fit driving of the transmission group, movable extrusion arm in two pairs of extrusion arms acts simultaneously, respectively from the pre-splicing frame component of photovoltaic axially and radially extruded on pedestal, change the present situation for first compressing axially the photovoltaic pre-splicing frame component pre-splicing frame component of radial compression photovoltaic again in the prior art, to improve extruding efficiency.

Description

A kind of pre-splicing frame component pressurizing unit of photovoltaic

Technical field

The present invention relates to energy technology field, and in particular to heliotechnics.

Background technology

Application No. 201120225752.X patent is related to a kind of pre-splicing frame component pressurizing unit of photovoltaic, including Pedestal and the extrusion arm being arranged on pedestal, extrusion arm are four, form two pairs, first pair of extrusion arm is right along the axial direction of pedestal Claim to set, radial symmetric of second pair of extrusion arm along pedestal is set, with reference to the accompanying drawing of above-mentioned patent application document.First pair of extruding Extrusion arm fixed setting in arm, is set to the first fixed press arm, and another extrusion arm is driven by the first cylinder, is set to the One movable extrusion arm；Extrusion arm fixed setting in second pair of extrusion arm, is set to the second fixed press arm, another extruding Arm is driven by the second cylinder, is set to the second movable extrusion arm.

The content of the invention

Technical problem solved by the invention：In the pre-splicing frame component pressurizing unit of photovoltaic, the first work how is realized The mechanical linkage of dynamic extrusion arm and the second movable extrusion arm, to improve extruding efficiency.

In order to solve the above technical problems, the present invention provides following technical scheme：A kind of pre-splicing frame component of photovoltaic squeezes Pressure device, including pedestal, two pairs of extrusion arms being arranged on pedestal, it is any that a fixed press arm and one are provided with to extrusion arm Movable extrusion arm, the movable extrusion arm in two pairs of extrusion arms pass through the fit linkage of transmission group.

Under the fit driving of the transmission group, the movable extrusion arm in two pairs of extrusion arms acts simultaneously, respectively from axial direction With the pre-splicing frame component of photovoltaic on radial compression pedestal, it is pre-splicing that change first compresses axially photovoltaic in the prior art The present situation of the frame component pre-splicing frame component of radial compression photovoltaic again, to improve extruding efficiency.

The transmission group is fit, including plate-like base, be articulated on plate-like base rotating cylinder, be articulated on plate-like base And the rotary shaft in rotating cylinder；

The madial wall of rotating cylinder is provided with expansion link, and the length direction of expansion link points to the center of rotating cylinder；

Dish, the edge spill gap of dish are installed in rotary shaft；

The axial line of rotary shaft deviates the center line of rotating cylinder, and rotating cylinder rotates with expansion link, when rotation medial wall of the tube When the enough expansion links in the distance between dish edge stretch into the spill gap, expansion link stretches into the spill gap, and Drive dish rotation；When rotating medial wall of the tube and dish Edge Distance is more than the maximum length of expansion link, expansion link takes off From the spill gap.

As described above, if expansion link rotates positioned at the A places of rotation medial wall of the tube, the rotating cylinder, at A and dish type When the distance between part edge is equal to or less than the maximum length of expansion link, expansion link stretches into the spill gap, and expansion link supports It is pressed in the side wall of spill gap, and drives dish to rotate.With the rotation of rotating cylinder, at above-mentioned A with dish edge When distance is more than the maximum length of expansion link, the side wall of expansion link and spill gap disengages, and rotating cylinder can continue to rotate, but Dish no longer rotates with.In this way, the rotating cylinder driving dish rotation smaller angle that the anglec of rotation is larger, the anglec of rotation is not Accurate rotating cylinder can drive dish to rotate accurate angle.

In two pairs of extrusion arms, the first movable extrusion arm in first pair of extrusion arm is connected with the first transmission component, the One transmission component is connected with the rotating cylinder；The second movable extrusion arm in second pair of extrusion arm is connected with the second transmission component, Second transmission component and the rotation axis connection.

The fit action of transmission group, the first transmission component drive the first movable extrusion arm, and the second transmission component driving second is lived Dynamic extrusion arm.Due to the rotation angle accuracy of dish, therefore, rotary shaft squeezes by the second transmission component the second activity Pressure arm precise displacement, the pre-splicing frame component of photovoltaic is obtained accurate radial compression, radial compression in place after, rotating cylinder With certain free rotation amplitude, it can't be driven, so, it is possible in rotating cylinder, rotary shaft described in the amplitude internal rotation Ensure axially and radially being pressed into place for the pre-splicing frame component of photovoltaic.

The first movable extrusion arm is arranged on the first transmission component by screw rod and clamp nut.Loosen fastening spiral shell Mother, screw rod can be with respect to the first transmission component displacements, during to suitable location, clamp nut standing screw, in this way, the first activity is squeezed The position of pressure arm can be adjusted.In the case where the first movable extrusion arm and the second movable extrusion arm interaction relation are certain, The adjustment of first movable extrusion arm position, it can adapt to the pre-splicing frame component of the different photovoltaic of size.

Brief description of the drawings

The present invention is described further below in conjunction with the accompanying drawings：

Fig. 1 is a kind of schematic diagram of the pre-splicing frame component pressurizing unit of photovoltaic；

Fig. 2 is the fit planar structure schematic diagram of transmission group；

Fig. 3 is the fit stereogram of transmission group；

Fig. 4 is rotary shaft and the combining structure schematic diagram of brake apparatus in transmission group zoarium；

Fig. 5 is the schematic diagram at rotary shaft and another visual angle of the combining structure of brake apparatus in transmission group zoarium；

Fig. 6 is the structural representation of rotating cylinder in transmission group zoarium；

Fig. 7 is the structural representation of brake release slide block assembly in transmission group zoarium；

Fig. 8 is the structural representation of any annular detent in a pair of annular detents in transmission group zoarium.

Symbol description in figure：

10th, pedestal；

21st, the first movable extrusion arm；211st, screw rod；212nd, clamp nut；22nd, the second movable extrusion arm；23rd, first fix Extrusion arm；24th, the second fixed press arm；

30th, the first transmission component；31st, gear member；310th, gear member mounting seat；32nd, screw mandrel；33rd, movable block；341st, transfer Component axle；342nd, middle rotating disk；343rd, driven sprocket；35th, drive sprocket；36th, chain；

40th, the second transmission component；41st, travelling gear；42nd, rack；420th, rack seat；43rd, power transmission shaft；430th, power transmission shaft Seat；

A10, plate-like base；

A20, rotating cylinder；A21, expansion link；A22, brake release accessory；

A30, rotary shaft；A31, dish；A32, spill gap；

A40, brake apparatus；A41, braking pedestal；A410, sliding block chute；A42, brake assemblies；A420, a pair of loop systems Moving part；A421, V-arrangement chute；A422, tipper；A423, straight trough；A424, locating piece；A43, brake release slide block assembly； A431, slide straight-bar；A432, braking solution lock slide；A433, trip lever；A434, alignment pin；

50th, the pre-splicing frame component of photovoltaic.

Embodiment

Detailed description below is referring to figs. 1 to Fig. 8.

A kind of pre-splicing frame component pressurizing unit of photovoltaic, including pedestal 10, two pairs of extrusion arms being arranged on pedestal, Any to be provided with a fixed press arm and a movable extrusion arm to extrusion arm, the movable extrusion arm in two pairs of extrusion arms passes through biography Dynamic assembly a linkages.

The transmission group zoarium a, including plate-like base a10, be articulated on plate-like base rotating cylinder a20, be articulated in disk Rotary shaft a30 on shape pedestal and in rotating cylinder.

The madial wall of rotating cylinder is provided with expansion link a21, and the length direction of expansion link points to the center of rotating cylinder.Rotary shaft On dish a31, the edge spill gap a32 of dish are installed.The axial line of rotary shaft deviates the center of rotating cylinder Line, rotating cylinder rotate with expansion link, when rotation the distance between medial wall of the tube and dish edge expansion link enough stretch into institute When stating spill gap, expansion link stretches into the spill gap, and drives dish to rotate；When rotation medial wall of the tube and dish side When edge distance is more than the maximum length of expansion link, expansion link departs from the spill gap.

The expansion link a21 includes tubular elements, extensible member, expansion link spring, and expansion link spring is arranged in tubular elements, stretched Contracting part is plugged in tubular elements and is pressed on expansion link spring.

Spill gap a32 quantity is three, and circumference of three spill gap along dish a31 stretches to being uniformly distributed Bar a21 drives dish to rotate 120 degree from any spill gap of three spill gap is stretched into the spill gap is departed from.

As described above, if three spill gap are respectively the first gap, the second gap, the 3rd gap, original state, First gap is in B location, and the second gap is in location of C, and the 3rd gap is in D positions.The expansion link rotated with rotating cylinder is stretched Enter the first gap, after driving dish rotates 120 degree, expansion link departs from the first gap, and now, the first gap is in C positions Put, the second gap is in D positions, and the 3rd gap is in B location.Afterwards, with the expansion link that rotating cylinder rotates because length is inadequate And cross the second gap.Afterwards, the expansion link rotated with rotating cylinder stretches into the 3rd gap, and driving dish rotates 120 degree Afterwards, expansion link departs from the 3rd gap, and now, the first gap is in D positions, and the second gap is in B location, and the 3rd gap is in C Position.So repeatedly, rotating cylinder continuously rotates, and the rotation of dish interval identical time is once, the angle phase rotated every time Together.Specifically, rotating cylinder rotates a circle, and dish rotates 1/3rd weeks.

The brake apparatus a40 braked to rotary shaft a30, rotating cylinder a20 madial wall are installed on plate-like base a10 It is provided with the brake release accessory a22 coordinated with the brake apparatus.

The brake apparatus a40 include be arranged on plate-like base a10 on braking pedestal a41, installed in braking pedestal on Brake assemblies a42, be slidably fitted in braking pedestal on brake release slide block assembly a43；Under normality, brake assemblies braking rotation Rotating shaft a30.The brake release accessory is one section of arc block being arranged in rotation medial wall of the tube.Rotating cylinder is with expansion link A21 and brake release accessory a22 rotations, when rotation medial wall of the tube and the distance between dish a31 edges expansion link enough are stretched When entering the spill gap a32, the brake release accessory contacts the brake release slide block assembly, and drives the braking solution Except slide block assembly slides on braking pedestal a41, brake release slide block assembly drives the brake assemblies a42, brake assemblies solution Except the braking to rotary shaft, synchronously, expansion link stretches into the spill gap, and drives dish to rotate.On the inside of rotating cylinder When wall is more than the maximum length of expansion link with dish Edge Distance, expansion link departs from the spill gap, the brake release Accessory disengages with the brake release slide block assembly, and the brake release slide block assembly resets, and the brake assemblies reset, Brake assemblies are braked to rotary shaft again.

As described above, one section of arc block and brake release slide block assembly offset beginning when, brake assemblies are released to rotation The braking of axle, expansion link stretch into spill gap and start to drive dish rotation；One section of arc block and brake release slide block assembly Offset holding a period of time, in this time, rotary shaft is not braked by brake assemblies, expansion link driving dish rotation；One When section arc block and brake release slide block assembly disengage, expansion link departs from dish, brake assemblies brake rotation shaft again. The setting of brake apparatus, it is braked after making dish and rotary shaft rotation predetermined angular, to ensure that dish and rotary shaft are every The angle of secondary rotation is predetermined, accurate.

On brake apparatus a40, the brake assemblies a42 is hinged including head end and tail end is resiliently connected together A pair of annular detent a420, a pair of annular detents surround the rotary shaft a30 and with rotary shaft CONTACT WITH FRICTION.A pair of rings The tail end of shape moving part opens up V-arrangement chute a421, is combined with V-arrangement chute and slides straight-bar a431, slides straight-bar and is arranged on braking Solving on lock slide a432, braking solution lock slide coordinates in sliding block chute a410, and sliding block chute is opened on braking pedestal a41, The elastic component of reset is provided between sliding block chute and braking solution lock slide, braking solution lock slide is provided with and the brake release The trip lever a433 of accessory a22 contacts；Straight-bar, the braking solution lock slide, the trip lever of sliding is slided for brake release Block assembly a43 part.When solution lock slide moves linearly along sliding block chute to rotating shaft center direction, straight-bar is slided Make linear slide in V-arrangement chute, the tail end of a pair of annular detents opens, and a pair of annular detents are away from rotary shaft.

As described above, under the driving of one section of arc block, braking solution lock slide moves to rotation direction of principal axis, cunning thereon Row straight-bar drives the tail end of a pair of annular detents to open, i.e. the tail end of two annular detents in a pair of annular detents is remote From in this way, a pair of annular detents no longer locking rotary shaft, rotary shaft are freely rotatable；Now, the elastic component of the reset Gather elastic potential energy.When one section of arc block solves lock slide with the braking to be disengaged, the elastic component of the reset The braking solution lock slide is driven to reset, a pair of annular detents reset therewith, again brake rotation shaft.

On brake apparatus a40, the brake assemblies a42 also includes being arranged on determining for a pair of annular detent a420 tail ends Position block a424, locating piece open up positioning hole.The brake release slide block assembly a43 also includes being arranged on the braking solution lock slide A432 it is upper and with the positioning hole coordinate alignment pin a434.The V-arrangement chute a421 includes one section of tipper a422 and one section Straight trough a423, one section of straight trough is away from the rotary shaft a30 and one section of tipper is close to the rotary shaft, one section of straight trough The line of travel of lock slide is solved parallel to the alignment pin and parallel to braking.

As described above, braking solution lock slide moves to rotation direction of principal axis, slides straight-bar and is slided first in one section of straight trough, Alignment pin is extracted from positioning hole.Afterwards, slide straight-bar to slide in one section of tipper, the tail end of a pair of annular detents is mutual It is remote.When braking solution lock slide is to away from rotation direction of principal axis reset movement, slides straight-bar and slided in one section of tipper, a pair of rings The tail end of shape moving part is drawn close, again brake rotation shaft；Afterwards, slide straight-bar to slide in one section of straight trough, alignment pin is inserted again Enter positioning hole, the state of a pair of annular detent brake rotation shafts is locked, to improve a pair of annular detent brake rotation shafts Validity and stability.

The fit workflow of the transmission group is as follows：Rotating cylinder a20 is with expansion link a21 and brake release accessory a22 Rotation, when brake release accessory a22 drives brake release slide block assembly a43, brake release slide block assembly a43 driving brake assemblies When a42 releases the braking to rotary shaft a30, expansion link a21 stretches into spill gap a32, and drives dish a31 to rotate predetermined angle Degree；Afterwards, expansion link a21 departs from spill gap, and synchronously, brake release accessory a22 and brake release slide block assembly a43 departs from Contact, again brake assemblies a42 resets and brake rotation shaft a30.

With rotating cylinder a20 rotation, when expansion link a21 stretches into next spill gap a32, brake release coordinates a22 Synchronously contacted with the brake release slide block assembly a43, and drive its action.In this way, continuous rotating cylinder a20 rotation fortune It is dynamic, intermittent dish a31 and rotary shaft a30 rotary motion are converted into, and dish a31 and rotary shaft a30 revolve every time The angle turned is fixed.

Two pairs of extrusion arms, respectively first pair of extrusion arm and second pair of extrusion arm, first pair of extrusion arm, which includes first, to be fixed 23 and first movable extrusion arm 21 of extrusion arm, second pair of extrusion arm include the second fixed press arm 24 and the second movable extrusion arm 22。

First movable extrusion arm 21 is connected with the first transmission component 30, and the first transmission component is connected with the rotating cylinder a20； Second movable extrusion arm 22 is connected with the second transmission component 40, and the second transmission component is connected with the rotary shaft a30.

First transmission component 30 includes transfer component, gear member 31, screw mandrel 32, movable block 33；The transfer component Linked with the rotating cylinder a20；The gear member links with the transfer component, and the center of gear member opens up screwed hole；It is described Screw mandrel coordinates with the screwed hole；The movable block is arranged on the screw mandrel；The first movable extrusion arm 21 is arranged on institute State on movable block.Wherein, transfer component include be arranged on pedestal on transfer component axle 341, on transfer component axle Middle rotating disk 342 and driven sprocket 343, middle rotating disk 342 are fixedly connected with driven sprocket 343, are installed on the rotating cylinder a20 Drive sprocket 35, drive sprocket are connected with driven sprocket by chain 36.The middle rotating disk engages with the gear member 31, institute State gear member to be articulated in gear member mounting seat 310, gear member mounting seat is arranged on pedestal 10.

Second transmission component 40 includes the travelling gear 41 and rack 42 of engagement, and the travelling gear is arranged on transmission On axle 43, rotary shaft a30 described in axis connection is driven, the second movable extrusion arm 22 is arranged on the rack.Wherein, rack It is slidably fitted on rack seat 420, rack seat is arranged on pedestal 10, and the rack seat is provided with drive axle seat 430, the biography Moving axis is arranged on the drive axle seat.

The first movable extrusion arm 21 is arranged on the first transmission component 30 by screw rod 211 and clamp nut 212.

In practical operation, the pre-splicing frame component of photovoltaic is placed on pedestal 10, between two pairs of extrusion arms.Transmission Assembly a is acted, and rotating disk 342 during its rotating cylinder a20 is driven by chain 36, gear member 31 acts, and screwed hole thereon drives Dynamic screw mandrel 32 moves linearly, and screw mandrel drives 33 and first movable extrusion arm 21 of movable block to move linearly.The fit rotation of transmission group Axle a30 drives travelling gear 41 to act by power transmission shaft 43, and travelling gear driving rack 42 moves linearly, the second movable extrusion arm 22 rectilinear movements.Above-mentioned first movable extrusion arm coordinates axial direction of the first fixed press arm 23 to the pre-splicing frame component of photovoltaic Extruded, above-mentioned second movable extrusion arm coordinates the second fixed press arm 24 to enter the radial direction of the pre-splicing frame component of photovoltaic Row extruding.Wherein, the ratio of the first movable extrusion arm and the second movable extrusion arm displacement depends on the pre-splicing frame of photovoltaic The axial length of component and the ratio of radical length.

Above content is only the better embodiment of the present invention, for one of ordinary skill in the art, according to the present invention Thought, there will be changes, this specification content should not be construed as to this hair in specific embodiments and applications Bright limitation.

Claims (9)

1. a kind of pre-splicing frame component pressurizing unit of photovoltaic, including pedestal (10), two pairs of extrusion arms being arranged on pedestal, It is any that a fixed press arm and a movable extrusion arm are provided with to extrusion arm, it is characterised in that：Activity in two pairs of extrusion arms Extrusion arm passes through transmission group fit (a) linkage.

A kind of 2. pre-splicing frame component pressurizing unit of photovoltaic as claimed in claim 1, it is characterised in that：The transmission group Fit (a), including plate-like base (a10), be articulated on plate-like base rotating cylinder (a20), be articulated on plate-like base and position In the rotary shaft (a30) in rotating cylinder；

The madial wall of rotating cylinder is provided with expansion link (a21), and the length direction of expansion link points to the center of rotating cylinder；

Dish (a31), the edge spill gap (a32) of dish are installed in rotary shaft；

The axial line of rotary shaft deviates the center line of rotating cylinder, and rotating cylinder rotates with expansion link, when rotation medial wall of the tube and disk When the enough expansion links in the distance between shape part edge stretch into the spill gap, expansion link stretches into the spill gap, and drives Dish rotates；When rotating medial wall of the tube and dish Edge Distance is more than the maximum length of expansion link, expansion link departs from institute State spill gap；

In two pairs of extrusion arms, the first movable extrusion arm (21) in first pair of extrusion arm connects with the first transmission component (30) Connect, the first transmission component is connected with the rotating cylinder (a20)；The second movable extrusion arm (22) and second in second pair of extrusion arm Transmission component (40) is connected, and the second transmission component is connected with the rotary shaft (a30).

A kind of 3. pre-splicing frame component pressurizing unit of photovoltaic as claimed in claim 2, it is characterised in that：Spill gap (a32) quantity is three, and circumference of three spill gap along dish (a31) is to being uniformly distributed, and expansion link (a21) is from stretching into Any spill gap of three spill gap rotates 120 degree to the spill gap, driving dish is departed from.

A kind of 4. pre-splicing frame component pressurizing unit of photovoltaic as claimed in claim 2, it is characterised in that：Plate-like base (a10) brake apparatus (a40) braked to rotary shaft (a30) is installed on, the madial wall of rotating cylinder (a20) be provided with The brake release accessory (a22) that the brake apparatus coordinates；

The brake apparatus includes the braking pedestal (a41) on plate-like base (a10), the system on braking pedestal Dynamic component (a42), the brake release slide block assembly (a43) being slidably fitted on braking pedestal；Under normality, brake assemblies braking rotation Rotating shaft (a30)；

The brake release accessory is one section of arc block being arranged in rotation medial wall of the tube；

Rotating cylinder rotates with expansion link (a21) and brake release accessory (a22), when rotation medial wall of the tube and dish (a31) When the enough expansion links in the distance between edge stretch into spill gap (a32), the brake release accessory contacts the braking Slide block assembly is released, and drives the brake release slide block assembly to be slided on braking pedestal (a41), brake release slide block assembly The brake assemblies (a42) are driven, brake assemblies release the braking to rotary shaft, and synchronously, expansion link stretches into the spill and slitted Mouthful, and drive dish to rotate；

When rotating medial wall of the tube and dish Edge Distance is more than the maximum length of expansion link, expansion link departs from the spill and slitted Mouthful, the brake release accessory disengages with the brake release slide block assembly, and the brake release slide block assembly resets, institute Brake assemblies reset is stated, brake assemblies are braked to rotary shaft again.

A kind of 5. pre-splicing frame component pressurizing unit of photovoltaic as claimed in claim 4, it is characterised in that：The braking group Part (a42) includes that head end is hinged and a pair of annular detents (a420) that tail end is resiliently connected together, a pair of annulars Brake component surround the rotary shaft (a30) and with rotary shaft CONTACT WITH FRICTION；

The tail end of a pair of annular detents opens up V-arrangement chute (a421), is combined with V-arrangement chute and slides straight-bar (a431), slided Straight-bar is arranged on braking solution lock slide (a432), and braking solution lock slide coordinates in sliding block chute (a410), and sliding block chute is opened It is located on braking pedestal (a41), the elastic component of reset, braking solution lock slide is provided between sliding block chute and braking solution lock slide It is provided with the trip lever (a433) contacted with the brake release accessory (a22)；It is described to slide straight-bar, the braking unblock cunning Block, the part that the trip lever is brake release slide block assembly (a43)；

When solution lock slide moves linearly along sliding block chute to rotating shaft center direction, slide straight-bar and make in V-arrangement chute directly Line slides, and the tail end of a pair of annular detents opens, and a pair of annular detents are away from rotary shaft.

A kind of 6. pre-splicing frame component pressurizing unit of photovoltaic as claimed in claim 5, it is characterised in that：The braking group Part (a42) also includes the locating piece (a424) for being arranged on a pair of annular detent (a420) tail ends, and locating piece opens up positioning hole；

The brake release slide block assembly (a43) also include being arranged on braking solution lock slide (a432) and with the positioning The alignment pin (a434) that hole coordinates；

The V-arrangement chute (a421) includes one section of tipper (a422) and one section of straight trough (a423), and one section of straight trough is away from the rotation Rotating shaft (a30) and one section of tipper close to the rotary shaft, one section of straight trough parallel to the alignment pin and parallel to The line of travel of braking solution lock slide.

A kind of 7. pre-splicing frame component pressurizing unit of photovoltaic as claimed in claim 2, it is characterised in that：Described first lives Dynamic extrusion arm (21) is arranged on the first transmission component (30) by screw rod (211) and clamp nut (212).

A kind of 8. pre-splicing frame component pressurizing unit of photovoltaic as claimed in claim 2, it is characterised in that：Described first passes Dynamic component (30) includes transfer component, gear member (31), screw mandrel (32), movable block (33)；

The transfer component links with the rotating cylinder (a20)；

The gear member links with the transfer component, and the center of gear member opens up screwed hole；

The screw mandrel coordinates with the screwed hole；

The movable block is arranged on the screw mandrel；

The first movable extrusion arm (21) is arranged on the movable block.

A kind of 9. pre-splicing frame component pressurizing unit of photovoltaic as claimed in claim 2, it is characterised in that：Described second passes Dynamic component (40) includes the travelling gear (41) and rack (42) of engagement, and the travelling gear is arranged on power transmission shaft (43), is passed Moving axis connects the rotary shaft (a30), and the second movable extrusion arm (22) is arranged on the rack.