CN117329374B

CN117329374B - Resistance-free corrugated compensator

Info

Publication number: CN117329374B
Application number: CN202311630165.2A
Authority: CN
Inventors: 韩青云; 吉顺荣; 张载云
Original assignee: Jiangsu Hongbo Machinery Manufacturing Co ltd
Current assignee: Jiangsu Hongbo Machinery Manufacturing Co ltd
Priority date: 2023-12-01
Filing date: 2023-12-01
Publication date: 2024-02-20
Anticipated expiration: 2043-12-01
Also published as: CN117329374A

Abstract

The invention relates to the technical field of compensators, and discloses a non-resistance type corrugated compensator which comprises a tray receiving mechanism, wherein a zooming mechanism is sleeved on the outer side of the left end of the tray receiving mechanism, a telescopic pipe is movably connected to the inner ring of the left end of the zooming mechanism, the right end of the telescopic pipe is covered and connected on the outer side of the left end of the tray receiving mechanism, a sliding mechanism penetrates through and is fixedly connected with the inner ring of the left end of the telescopic pipe, and the left end of the sliding mechanism is fixedly connected with a corrugated mechanism. The inner ring of the tray receiving mechanism can be timely adjusted at the gas inlet position when the inner side wall of the tray receiving mechanism receives the extrusion of the gas flow, the inlet size can be timely and conveniently adjusted when the gas flow is increased, the unsmooth gas flow is avoided, the corrugated mechanism can be limited by the embedding mechanism after the inner gas flow fluctuates inside and outside through the side wall of the corrugated mechanism, the fluctuation of the gas flow can be adjusted by the inner side wall of the corrugated mechanism in a telescopic manner, and the resistance of the gas flow in the increasing process can be reduced.

Description

Resistance-free corrugated compensator

Technical Field

The invention relates to the technical field of compensators, in particular to a non-resistance type ripple compensator.

Background

In order to compensate for additional stress caused by temperature difference, mechanical vibration and the like, a compensator is usually arranged on a container shell or a pipeline, so that the effective expansion and contraction deformation of a corrugated pipe of a working main body of the compensator can be utilized, and the pipeline deformation or damage caused by thermal elongation, temperature stress and the like after the temperature in a heating pipeline can be prevented.

Publication number CN 104832737A discloses a bellows compensator, in which the thrust generated in the balance bellows by the fluid pressure and the thrust of the first and second bellows are compared to each other to push, and the balance compensator is deformed and unstable, so that in combination with the prior art, the impact force of the fluid at the inlet is large, the thrust is not buffered, the side wall of the compensator is difficult to restore to the original position after being deformed, and then the original expansion state of the compensator may be difficult to maintain in the later use.

Disclosure of Invention

The invention aims at: the invention provides a resistance-free corrugated compensator, which aims to solve the problem that the expansion and contraction amount of the corrugated compensator is difficult to recover after larger fluid thrust.

The invention adopts the following technical scheme for realizing the purpose.

The utility model provides an unobstructed resistance ripple compensator, includes the flange mechanism, the left end outside of flange mechanism has cup jointed the mechanism that zooms, the left end inner circle swing joint of mechanism that zooms has flexible pipe, the right-hand member cover of flexible pipe is in the left end outside of flange mechanism, the left end inner circle of flexible pipe runs through and fixedly connected with slide mechanism, the left end fixedly connected with ripple mechanism of slide mechanism, the left end outside fixedly connected with folding cover of ripple mechanism, the outer end of mechanism that zooms runs through and swing joint has an embedding mechanism, the middle section position of embedding mechanism runs through the outer end of slide mechanism, the left end outside of folding cover runs through and swing joint has the backup pad, the left end of embedding mechanism runs through and swing joint in the outside end of backup pad, folding cover the left end inner circle of backup pad runs through and is connected with overhanging mechanism, the right-hand member runs through and swing joint in the inside end of folding cover, through the inside and outside of inner circle of flange mechanism and fixedly connected with ripple mechanism, automatic transfer air current and carry to the inside of ripple mechanism, then according to the inside of the automatic shrink transfer of the inner circle of flange mechanism, the inside of ripple mechanism is kept stable ripple mechanism of inner wall through the steady state of the ripple of adjustable inner wall of ripple mechanism of pressure that can be passed through to the steady side wall of ripple mechanism of adjusting, the steady operation of the ripple that can be followed.

Further, the tray receiving mechanism comprises a rotary drum, a flange plate, a cylinder, a movable block, a support rod and a slide rod, wherein the movable block, the support and the outer ring of the support rod are connected with the inner ring of the zooming mechanism in a penetrating manner, when the positions of the movable block and the support are outwards telescopic, the inner ring of the zooming mechanism can be pushed inwards and outwards, and the side wall of the support is positioned at the inner side of the telescopic pipe, so that the right end of the sliding mechanism can rotate the side wall of the support.

Further, the left end fixed connection of rotary drum in the inner circle of ring flange, the left side swing joint of ring flange in the right-hand member of drum, movable block the support with the outer lane of bracing piece through connection in the inner circle of drum, the rotary drum is by the concatenation of polylith plate, the outside sliding connection of slide bar in the clearance inboard of rotary drum, the position of rotary drum can carry out inside and outside shrink with the help of the position of slide bar to drive the position of support and shrink inside and outside the regulation, along with the air current dynamics is bigger when, the inner circle space of rotary drum outwards enlarges, can drive the increase of the circle diameter of otic placode.

Further, the scaling mechanism comprises an ear plate and a movable ring, the ear plate is formed by splicing four plates, the outer side of the side end of the movable ring is slidably connected between the inner sides of gaps of the ear plate, the central point of the inner end of the ear plate is fixedly connected to the outer side wall of the tray receiving mechanism, the peripheral part of the inner end of the ear plate is slidably connected to the gap area of the tray receiving mechanism, the outer end part of the ear plate is fixedly connected to the right end of the embedding mechanism, the left side of the ear plate is slidably connected to the outer side of the right end of the telescopic pipe, and the ring diameter of the ear plate is increased, so that the outer end of the support can be pulled outwards.

Further, slide mechanism includes slide tube, fly leaf and interior extension pipe, the left end of slide tube with interior right-hand member fixed connection of extension pipe is in the same place, the inner circle of fly leaf run through and fixed connection in the slide tube in the outside of the tie point department of extension pipe, the outside end of fly leaf run through and swing joint in embedded mechanism's lateral wall middle section, interior left end outside swing joint of extension pipe in corrugated mechanism's right-hand member is inboard, and the position of fly leaf can support fixedly embedded mechanism position, avoids embedded mechanism's lateral wall displacement.

Further, the ripple mechanism includes bellows, evagination circle and interior dog, the right-hand member inner circle swing joint of bellows in the left end outside of sliding mechanism, the outside swing joint of bellows in the inner of embedded mechanism, the outer end lateral wall clearance position sliding connection of evagination circle in the inner lateral wall department of embedded mechanism, the lateral wall setting of bellows is folding form, the evagination circle sets up the folding point outer end bulge position of bellows, interior dog set up in the outer end of evagination circle, when the position of bellows is driven outwards to bulge by the air current atmospheric pressure, the inner of embedded mechanism can in time be spacing and inwards push the outside of bellows, and the inside air current fluctuation of supplementary ripple mechanism changes steady state gradually, and the inside of air current through bellows inboard line and elasticity promotion.

Further, the embedding mechanism comprises a movable rod and a clamping plate, the right end of the movable rod is connected with the outer end of the zooming mechanism in a penetrating manner, the outer end of the clamping plate is fixedly connected with the side wall part of the movable rod, the inner end of the clamping plate can be opposite to the concave part at the side wall of the corrugated mechanism, the clamping plate can limit the part of the corrugated mechanism, when the air flow is increased, the part of the corrugated pipe is driven by the air flow to extrude outwards to bulge and deform, and the clearance part of the outer convex ring can be limited by the inner end of the clamping plate.

Further, the overhanging mechanism comprises a sleeve, an internal thread and a tail connecting pipe, the internal thread is arranged on the inner side of the sleeve, the right end of the tail connecting pipe is fixedly connected with the left end of the sleeve, the right end of the sleeve is connected with the left end of the folding sleeve in a penetrating manner, air flow becomes stable gradually from the inside of the corrugated mechanism to the inside of the overhanging mechanism, the air flow enters the inside of the overhanging mechanism, the pressure difference shell of the air flow is reduced, and the inside of the internal thread can run more stably.

Compared with the prior art, the invention provides the non-resistance type ripple compensator, which has the following beneficial effects:

1. the inner ring of the flange mechanism can be timely adjusted in size at the gas inlet position when the extrusion of the gas flow is received through the inside of the side wall of the flange mechanism, the inlet can be timely and conveniently adjusted in size when the gas flow is increased, and the unsmooth gas flow is avoided.

2. According to the non-resistance type corrugated compensator, after the side wall of the corrugated mechanism fluctuates inside and outside the internal air flow, the corrugated mechanism can be limited by the embedded mechanism, the corrugated mechanism and the inner end of the embedded mechanism can collide with each other, fluctuation of the air flow can be regulated by stretching and contracting inside and outside the side wall of the corrugated mechanism, dust on the inner wall can be shaken off in the process of stretching and contracting inside and outside the side wall of the corrugated mechanism, the corrugated mechanism is pushed back to the original position by means of the embedded mechanism, and the sufficient stretching amount of the corrugated mechanism is ensured to be maintained in the later stage.

3. The resistance-free corrugated compensator can maintain stable operation in the later stage of the air flow by gradually reducing the air flow after the air flow reaches the inside of the overhanging mechanism after the air flow passes through the inside of the corrugated mechanism for buffering.

Drawings

FIG. 1 is a schematic diagram of the overall structure connection of the present invention;

FIG. 2 is a schematic view showing the connection of related structures in the tray-receiving mechanism of the present invention;

FIG. 3 is a right side cross-sectional view of the structural connection between the zoom mechanism and the tray mechanism of the present invention;

FIG. 4 is a right side cross-sectional view of the male collar and insert mechanism of the present invention;

FIG. 5 is a right side partial cross-sectional view of the connection of the card and the internal related structure of the corrugating mechanism of the present invention;

FIG. 6 is a structural representation of the folding sleeve and overhanging mechanism of the present invention;

FIG. 7 is a detailed schematic diagram of the internal related structure of the overhanging mechanism of the present invention.

In the figure: 1. a tray receiving mechanism; 101. a rotating drum; 102. a flange plate; 103. a cylinder; 104. a movable block; 105. a bracket; 106. a support rod; 107. a slide bar; 2. a scaling mechanism; 201. ear plates; 202. a movable ring; 3. a telescopic tube; 4. a sliding mechanism; 401. a slide tube; 402. a movable plate; 403. an inner extension pipe; 5. a ripple mechanism; 501. a bellows; 502. an outer convex ring; 503. an inner stopper; 6. folding the sleeve; 7. an embedding mechanism; 701. a movable rod; 702. a clamping plate; 8. a support plate; 9. an overhanging mechanism; 901. a sleeve; 902. internal rotation patterns; 903. and (5) tail connecting pipes.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

As shown in fig. 1-7, the non-resistance type ripple compensator comprises a tray receiving mechanism 1, a zooming mechanism 2 is sleeved on the outer side of the left end of the tray receiving mechanism 1, a telescopic pipe 3 is movably connected to the inner ring of the left end of the zooming mechanism 2, the right end of the telescopic pipe 3 is covered on the outer side of the left end of the tray receiving mechanism 1, the inner ring of the left end of the telescopic pipe 3 is penetrated and fixedly connected with a sliding mechanism 4, the left end of the sliding mechanism 4 is fixedly connected with a ripple mechanism 5, the outer side of the left end of the ripple mechanism 5 is fixedly connected with a folding sleeve 6, the outer end of the zooming mechanism 2 is penetrated and movably connected with an embedding mechanism 7, the middle section part of the embedding mechanism 7 is penetrated through the outer end of the sliding mechanism 4, the outer side of the left end of the folding sleeve 6 is penetrated and movably connected with a supporting plate 8, the left end of the embedded mechanism 7 penetrates through and is movably connected to the outer side end of the supporting plate 8, the folding sleeve 6 and the inner ring of the left end of the supporting plate 8 are connected with the overhanging mechanism 9 in a penetrating manner, the right end of the overhanging mechanism 9 penetrates through and is movably connected to the inner side end of the left end of the folding sleeve 6, air flow is mobilized through inner and outer shrinkage of the inner ring of the tray mechanism 1 and is conveyed to the inside of the corrugated mechanism 5, then the inner wall of the corrugated mechanism 5 is regulated according to the size regulated by air, the side wall of the corrugated mechanism 5 can automatically deform to maintain stable fluctuation, the side wall of the corrugated mechanism 5 can be limited by the embedded mechanism 7 to enable the fluctuation of the air flow to maintain a stable state, and then the air flow pressure is gradually reduced after entering the inside of the overhanging mechanism 9 to stably operate.

As shown in fig. 1 and 3, in some embodiments, the disc splicing mechanism 1 includes a drum 101, a flange 102, a cylinder 103, a movable block 104, a support 105, a support bar 106 and a slide bar 107, the outer rings of the movable block 104, the support 105 and the support bar 106 are connected to the inner ring of the zooming mechanism 2 in a penetrating manner, when the inner rings of the movable block 104 and the support 105 are stretched out and drawn back, the inner ring of the zooming mechanism 2 can be pushed in and out, the left end of the drum 101 is fixedly connected to the inner ring of the flange 102, the left side of the flange 102 is movably connected to the right end of the cylinder 103, the outer rings of the movable block 104, the support 105 and the support bar 106 are connected to the inner ring of the cylinder 103 in a penetrating manner, the drum 101 is formed by splicing a plurality of blocks, the outer side of the slide bar 107 is connected to the inner side of the gap of the drum 101 in a sliding manner, the position of the drum 101 can be shrunk in and out by means of the position of the slide bar 107, and the inner ring of the part of the disc splicing mechanism 1 can be driven to shrink in and out when the air flow passes through the inner ring of the slide tube 401, the air flow volume is increased, when the air flow enters the inner ring part of the bellows mechanism 5, the inner part can be pulled in the sliding part 4, when the bellows 4 is pulled by the left end of the bellows 4 of the bellows mechanism 5, and the slide 4 is pulled by the inner part 4.

As shown in fig. 1 and 3, in some embodiments, the zoom mechanism 2 includes an ear plate 201 and a movable ring 202, where the ear plate 201 is formed by splicing four plates, the outer side of the side end of the movable ring 202 is slidably connected between the inner sides of the gaps of the ear plate 201, the center point of the inner end of the ear plate 201 is fixedly connected to the outer side wall of the tray mechanism 1, the periphery of the inner end of the ear plate 201 is slidably connected to the gap area of the tray mechanism 1, the outer end of the ear plate 201 is fixedly connected to the right end of the embedding mechanism 7, and the left side of the ear plate 201 is slidably connected to the outer side of the right side end of the telescopic tube 3.

As shown in fig. 1, in some embodiments, the sliding mechanism 4 includes a sliding tube 401, a movable plate 402 and an inner extension tube 403, where the left end of the sliding tube 401 and the right end of the inner extension tube 403 are fixedly connected together, the inner ring of the movable plate 402 penetrates through and is fixedly connected to the outer side of the connection point of the sliding tube 401 and the inner extension tube 403, the outer side end of the movable plate 402 penetrates through and is movably connected to the middle section of the side wall of the embedding mechanism 7, the outer side of the left end of the inner extension tube 403 is movably connected to the inner side of the right end of the corrugated mechanism 5, the position of the movable plate 402 can support and fix the position of the embedding mechanism 7, so as to avoid the side wall displacement of the embedding mechanism 7, and since the side wall of the bracket 105 is located on the inner side of the telescopic tube 3, the right end of the sliding mechanism 4 can rotate the side wall of the bracket 105, and as the airflow strength is larger, the inner ring space of the drum 101 expands outwards, the ring diameter of the ear plate 201 is increased, i.e. the outer end of the bracket 105 is pulled outwards, and the inner diameter of the telescopic tube 3 can be adjusted according to the airflow strength.

As shown in fig. 1 and fig. 4, in some embodiments, the corrugated mechanism 5 includes a corrugated tube 501, an outer convex ring 502 and an inner stop 503, where the inner ring at the right end of the corrugated tube 501 is movably connected to the outer side of the left end of the sliding mechanism 4, the outer side of the corrugated tube 501 is movably connected to the inner end of the embedded mechanism 7, the gap portion of the outer side wall of the outer convex ring 502 is slidably connected to the inner side wall of the embedded mechanism 7, the side wall of the corrugated tube 501 is folded, the outer convex ring 502 is disposed at the convex portion of the outer end of the folding point of the corrugated tube 501, the inner stop 503 is disposed at the outer end of the outer convex ring 502, and when the portion of the corrugated tube 501 is driven by the air pressure to bulge outwards, the inner end of the embedded mechanism 7 can limit the outer side of the corrugated tube 501 in time and push inwards, so as to assist the air flow fluctuation inside the corrugated mechanism 5 to gradually turn into a stable state.

As shown in fig. 1, fig. 4 and fig. 5, in some embodiments, the embedding mechanism 7 includes a movable rod 701 and a clamping plate 702, the right end of the movable rod 701 is connected to the outer end of the zoom mechanism 2 in a penetrating manner, the outer end of the clamping plate 702 is fixedly connected to the side wall of the movable rod 701, the inner end of the clamping plate 702 can be opposite to the concave part at the side wall of the corrugated mechanism 5, the clamping plate 702 can limit the part of the corrugated mechanism 5, the air flow passes through the inside of the corrugated mechanism 5, and when the air flow increases, the part of the corrugated pipe 501 is extruded and outwards and is outwards bulged by the air flow, the gap of the outer flange 502 can be limited by the inner end of the clamping plate 702, excessive displacement of the part of the corrugated pipe 501 can be avoided, and the side wall of the whole corrugated pipe 501 can keep stable fluctuation.

As shown in fig. 1, 6 and 7, in some embodiments, the overhanging mechanism 9 includes a sleeve 901, an internal thread 902 and a tail adapter 903, the internal thread 902 is disposed on the inner side of the sleeve 901, the right end of the tail adapter 903 is fixedly connected to the left end of the sleeve 901, the right end of the sleeve 901 is connected to the left end of the folding sleeve 6 in a penetrating manner, when the airflow from the inside of the ripple mechanism 5 to the inside of the overhanging mechanism 9 becomes stable, the airflow passes through the inner side of the ripple mechanism 5 and then enters the inside of the overhanging mechanism 9, the pressure difference of the airflow can be reduced, and the inner side of the internal thread 902 can operate more stably.

Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides a no resistance formula ripple compensator, includes flange mechanism (1), its characterized in that: the left end outside of the tray mechanism (1) is sleeved with a zooming mechanism (2), the left end inner ring of the zooming mechanism (2) is movably connected with a telescopic pipe (3), the right end of the telescopic pipe (3) is covered outside the left end of the tray mechanism (1), the left end inner ring of the telescopic pipe (3) penetrates through and is fixedly connected with a sliding mechanism (4), the left end of the sliding mechanism (4) is fixedly connected with a corrugated mechanism (5), the left end outside of the corrugated mechanism (5) is fixedly connected with a folding sleeve (6), the outer end of the zooming mechanism (2) penetrates through and is movably connected with an embedding mechanism (7), the middle section part of the embedding mechanism (7) penetrates through the outer end of the sliding mechanism (4), the left end outside of the folding sleeve (6) penetrates through and is movably connected with a supporting plate (8), the left end of the embedding mechanism (7) penetrates through and is movably connected with the outer end of the supporting plate (8), the left end of the folding sleeve (6) is fixedly connected with a corrugated mechanism (9), the left end of the inner ring (8) penetrates through and is connected with the inner wall of the inner ring (5) according to the moving regulating mechanism, the side wall of the ripple mechanism (5) can automatically deform to maintain stable fluctuation, the side wall of the ripple mechanism (5) can be limited by the embedded mechanism (7) to promote the fluctuation of air flow to maintain a stable state, and then the air flow pressure is gradually reduced after entering the inside of the overhanging mechanism (9) to stably operate;

the tray receiving mechanism (1) comprises a rotary drum (101), a flange plate (102), a cylinder (103), a movable block (104), a bracket (105), a supporting rod (106) and a sliding rod (107), wherein the movable block (104), the bracket (105) and the outer ring of the supporting rod (106) are connected with the inner ring of the zooming mechanism (2) in a penetrating way, and when the positions of the movable block (104) and the bracket (105) are stretched outwards, the inner ring of the zooming mechanism (2) can be pushed inwards and outwards;

the rotary drum (101) is formed by splicing a plurality of plates, the outer side of the sliding rod (107) is slidably connected to the inner side of a gap of the rotary drum (101), the part of the rotary drum (101) can be contracted inwards and outwards by means of the part of the sliding rod (107), and the part of the rotary drum (101) drives the part of the support (105) to be contracted inwards and outwards to be adjusted;

the telescopic mechanism comprises a lug plate (201) and a movable ring (202), wherein the lug plate (201) is formed by splicing four plates, the outer side of the side end of the movable ring (202) is slidably connected between the inner sides of gaps of the lug plate (201), the center point part of the inner end of the lug plate (201) is fixedly connected with the outer side wall part of the tray receiving mechanism (1), the periphery part of the inner end of the lug plate (201) is slidably connected with the gap area of the tray receiving mechanism (1), the outer end part of the lug plate (201) is fixedly connected with the right end of the embedding mechanism (7), and the left side of the lug plate (201) is slidably connected with the outer side of the right side end of the telescopic tube (3).

2. A resistance-free ripple compensator in accordance with claim 1, wherein: the sliding mechanism (4) comprises a sliding tube (401), a movable plate (402) and an inner extending tube (403), the left end of the sliding tube (401) is fixedly connected with the right end of the inner extending tube (403), the inner ring of the movable plate (402) penetrates through and is fixedly connected with the outer side of the connecting point of the sliding tube (401) and the inner extending tube (403), the outer side end of the movable plate (402) penetrates through and is movably connected with the middle section of the side wall of the embedding mechanism (7), the outer side of the left end of the inner extending tube (403) is movably connected with the inner side of the right end of the corrugated mechanism (5), and the position of the movable plate (402) can support and fix the position of the embedding mechanism (7) so as to avoid the side wall displacement of the embedding mechanism (7).

3. A resistance-free ripple compensator in accordance with claim 1, wherein: the corrugated mechanism (5) comprises a corrugated pipe (501), an outer convex ring (502) and an inner stop block (503), wherein the right end inner ring of the corrugated pipe (501) is movably connected to the outer side of the left end of the sliding mechanism (4), the outer side of the corrugated pipe (501) is movably connected to the inner end of the embedded mechanism (7), the gap part of the outer side wall of the outer convex ring (502) is slidably connected to the inner side wall of the embedded mechanism (7), the side wall of the corrugated pipe (501) is folded, the outer convex ring (502) is arranged at the protruding part of the folding point outer end of the corrugated pipe (501), the inner stop block (503) is arranged at the outer end of the outer convex ring (502), and when the part of the corrugated pipe (501) is driven to outwards bulge by air pressure, the inner end of the embedded mechanism (7) can timely limit the outer side of the corrugated pipe (501) and push inwards, and the air flow fluctuation inside the auxiliary corrugated mechanism (5) is gradually changed into a stable state.

4. A resistance-free ripple compensator in accordance with claim 1, wherein: the embedded mechanism (7) comprises a movable rod (701) and a clamping plate (702), the right end of the movable rod (701) is connected with the outer end of the zooming mechanism (2) in a penetrating mode, the outer end of the clamping plate (702) is fixedly connected with the side wall part of the movable rod (701), the inner end of the clamping plate (702) can be opposite to the concave part at the side wall part of the ripple mechanism (5), and the clamping plate (702) can limit the part of the ripple mechanism (5).

5. A resistance-free ripple compensator in accordance with claim 1, wherein: the external extending mechanism (9) comprises a sleeve (901), internal threads (902) and a tail connecting pipe (903), wherein the internal threads (902) are arranged on the inner side of the sleeve (901), the right end of the tail connecting pipe (903) is fixedly connected with the left end of the sleeve (901), the right end of the sleeve (901) is connected with the left end of the folding sleeve (6) in a penetrating manner, and air flow gradually becomes stable from the inside of the corrugated mechanism (5) to the inside of the external extending mechanism (9).