CN109704552B - Glass tube forming numerical control shaping machine with flow meter - Google Patents

Abstract

The invention relates to a glass tube forming numerical control shaping machine with a flow meter. The glass tube forming numerical control shaping machine with the flow meter comprises a numerical control machine table, a forming assembly, a heating assembly, a vacuum assembly and a control table, wherein a forming space is formed in the numerical control machine table, the forming assembly comprises a rotary driving piece and a rotary mandril, the rotary driving piece is arranged at the bottom of the forming space, the rotary mandril is arranged on the rotary driving piece and used for sleeving and installing a glass tube, the heating assembly is movably arranged on the side wall of the forming space and used for heating the glass tube, the vacuum assembly is adjacent to the rotary driving piece and used for vacuumizing the glass tube, the control table is adjacent to the numerical control machine table, and the rotary driving piece, the heating assembly and the vacuum assembly are electrically connected with the control table. The glass tube forming numerical control shaping machine with the flow meter is convenient for forming tubular glass.

Description

Glass tube forming numerical control shaping machine with flow meter

Technical Field

The invention relates to the technical field of glass forming, in particular to a glass tube forming numerical control shaping machine with a flow meter.

Background

Glass forming is the process of converting molten glass into a geometrically shaped article, which is referred to as primary or hot-end forming of the glass. The glass must be formed within a certain viscosity (temperature) range. During forming, the molten glass performs continuous heat exchange and heat transfer with the surrounding medium in addition to mechanical movement. The molten glass first changes from a viscous liquid state to a plastic state and then to a brittle solid state.

For example, chinese patent publication No. CN101767924A discloses an apparatus for manufacturing a channel glass from a flat glass. The device comprises a rack, two sets of power devices arranged at the beginning and the tail end of the rack, two sets of horizontal transmission roller ways, a preheating furnace, a rolling furnace and an annealing furnace which are positioned in the rack and horizontally penetrate through the rack in sequence, wherein a first-stage rolling mill, a second-stage rolling mill, a third-stage rolling mill and a shaping rolling mill are sequentially arranged in the rolling furnace, each set of horizontal transmission roller way comprises a transmission shaft, a plurality of paired helical gears and a plurality of horizontally arranged transmission rollers, and bearings of the transmission rollers are arranged on the rack.

However, the above prior art has the following drawbacks: which does not enable the shaping of tubular glass.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide a glass tube forming numerical control shaping machine with a flow meter, which is convenient for forming tubular glass.

In order to achieve the purpose, the invention provides the following technical scheme:

the utility model provides a glass pipe shaping numerical control trimmer with flowmeter, includes numerical control board, shaping subassembly, heating element, vacuum subassembly and control cabinet, be formed with the shaping space in the numerical control board, the shaping subassembly includes rotary driving piece and rotatory plug, rotary driving piece set up in the bottom in shaping space, rotatory plug install in rotary driving piece is last for the cover is established and is installed the glass pipe, heating element movably install in on the lateral wall in shaping space, be used for right the glass pipe heats, vacuum subassembly is close to rotary driving piece sets up, be used for right the intraductal evacuation of glass, the control cabinet is close to the numerical control board sets up, rotary driving piece heating element reaches vacuum subassembly all with control cabinet electric connection.

When the glass tube forming machine is used, a glass tube is sleeved on the rotating mandrel, the rotating driving piece drives the glass tube to rotate through the rotating mandrel, the heating assembly heats the glass tube, the vacuum assembly vacuumizes the inside of the glass tube, and the glass tube is attached to the rotating mandrel under the action of the external atmospheric pressure after being heated and deformed, so that the shape of the glass tube is changed to be the same as that of the rotating mandrel, and tubular glass is convenient to form.

Further, be provided with the installing frame on the diapire in shaping space, rotary driving spare set up in the installing frame.

Through adopting above-mentioned technical scheme, made things convenient for rotary driving piece's installation.

Further, the heating assembly comprises two heating structures which are arranged oppositely, and the rotating mandrel is positioned between the two heating structures.

By adopting the technical scheme, the heating assembly is convenient to heat the two opposite sides of the glass tube.

Further, each heating structure is connected with a fuel gas source through a gas pipe, and a flow meter is installed on the gas pipe.

By adopting the technical scheme, the gas flow meter can monitor the gas quantity of the heating structure conveniently, and then the heating quantity of the heating structure is controlled.

Further, the vacuum assembly comprises a vacuum pump and a connecting pipe, the vacuum pump is installed in the installation frame, one end of the connecting pipe is connected with the vacuum pump, and the other end of the connecting pipe extends to the bottom of the rotary mandrel.

By adopting the technical scheme, the vacuum pump is convenient to use for vacuumizing operation in the glass tube.

Further, the vacuum assembly further comprises a sealing plug, and the sealing plug is arranged at the top end of the rotating core rod and used for sealing the top end of the glass tube.

By adopting the technical scheme, the sealing plug is utilized to seal the top end of the rotary core rod, so that the vacuum pump can be used for vacuumizing the glass tube.

Furthermore, the numerical control machine platform comprises a base and accommodating seats arranged on two opposite sides of the base, the forming space is located between the two accommodating seats, and an accommodating space is formed in each accommodating seat and used for accommodating the glass tube.

Through adopting above-mentioned technical scheme, utilize the storage space of accepting the seat accomodates glass pipe or other parts, improved and accomodate efficiency.

Further, the control cabinet comprises a base, a support column and a control table top, wherein the support column is installed on the base, and the control table top is arranged at the top end of the support column.

By adopting the technical scheme, the numerical control machine is conveniently controlled by the control table board.

Furthermore, the surface of the control table top is an inclined surface, and a plurality of control buttons are arranged on the inclined surface.

By adopting the technical scheme, the installation of the control buttons is convenient.

Furthermore, the control buttons are all cylindrical, and integrated control buttons are further arranged on the inclined surface.

Through adopting above-mentioned technical scheme, conveniently utilize integrated control button one-key control digit control machine tool realizes the following procedure of one-key control promptly: the rotation of the rotating core rod, the heating ignition of the heating assembly, and the vacuum pumping operation of the vacuum rod.

In conclusion, the invention has the following beneficial effects:

1. through the setting of rotatory plug and heating element, when using, with glass pipe box locate rotatory plug on, rotatory driving piece passes through rotatory plug drives the glass pipe is rotatory, heating element is right the glass pipe heats, vacuum element is right the intraductal evacuation operation that carries out of glass the glass pipe is heated the deformation back, because of receiving the effect of external atmospheric pressure, attached on rotatory plug, thereby make the shape of glass pipe become with the shape of rotatory plug is the same, the shaping tubulose glass of being convenient for.

Drawings

FIG. 1 is a perspective view of a glass tube forming numerical control shaper with a flow meter according to an embodiment.

Fig. 2 is a perspective view of another perspective view of the glass tube forming numerically controlled shaper with a flow meter shown in fig. 1.

Fig. 3 is a partially enlarged view of a portion a in fig. 1.

Fig. 4 is a perspective view of a heating assembly and a forming assembly according to an embodiment.

In the figure, 100, a glass tube forming numerical control shaping machine with a flow meter; 10. a numerical control machine; 11. a base; 12. an accommodating seat; 125. a storage space; 128. a U-shaped groove; 1281. a first sliding groove; 1282. a second sliding groove; 1283. an arc-shaped connecting groove; 13. a first guide bar; 14. a second guide bar; 15. a molding space; 157. a guide rail; 16. installing a frame; 168. an arc-shaped fire blocking sheet; 18. mounting an arm; 181. inserting the gap; 185. a sliding groove; 20. a molding assembly; 21. a rotary drive member; 22. rotating the core rod; 30. a heating assembly; 35. a heating structure; 351. a flame projecting head; 352. a telescopic guide rod; 355. a guide structure; 40. a vacuum assembly; 41. a vacuum pump; 43. a sealing plug; 50. a console; 51. a base; 52. support column, 53, control table; 535. an inclined surface; 538. a control button; 60. a positioning assembly; 61. a sliding plate; 62. the bar is stirred; 63. a telescopic button; 635. and (5) positioning the rod.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Referring to fig. 1 and 2, a glass tube forming numerical control shaping machine 100 with a flow meter includes a numerical control machine 10, a forming assembly 20, a heating assembly 30, a vacuum assembly 40 and a console 50, a forming space 15 is formed in the numerical control machine 10, the forming assembly 20 includes a rotary driving member 21 and a rotary mandrel 22, the rotary driving member 21 is disposed at the bottom of the molding space 15, the rotary plug 22 is mounted on the rotary driving member 21, for sleeving and installing a glass tube, the heating assembly 30 is movably installed on the side wall of the forming space 15, for heating the glass tube, the vacuum assembly 40 being disposed adjacent to the rotary drive 21, for vacuumizing the glass tube, the console 50 is arranged adjacent to the numerical control machine 10, the rotary driving member 21, the heating assembly 30 and the vacuum assembly 40 are all electrically connected to the console 50.

When the glass tube forming machine is used, a glass tube is sleeved on the rotating mandrel 22, the rotating driving piece 21 drives the glass tube to rotate through the rotating mandrel 22, the heating assembly 30 heats the glass tube, the vacuum assembly 40 performs vacuum pumping operation on the glass tube, and the glass tube is attached to the rotating mandrel 22 under the action of the external atmospheric pressure after being heated and deformed, so that the shape of the glass tube is changed to be the same as that of the rotating mandrel 22, and tubular glass is formed conveniently.

An installation frame 16 is arranged on the bottom wall of the forming space 15, and the rotary driving piece 21 is arranged in the installation frame 16. The heating assembly 30 includes two heating structures 35, the two heating structures 35 are disposed opposite to each other, and the rotating mandrel 22 is located between the two heating structures 35. Each heating structure 35 is connected with a fuel gas source through an air pipe, and a flow meter is installed on the air pipe. The vacuum assembly 40 includes a vacuum pump 41 and a connecting pipe, the vacuum pump 41 is installed in the mounting frame 16, one end of the connecting pipe is connected to the vacuum pump 41, and the other end of the connecting pipe extends to the bottom of the rotary mandrel 22. The vacuum assembly 40 further comprises a sealing plug 43, and the sealing plug 43 is arranged at the top end of the rotary core rod 22 and is used for sealing the top end of the glass tube. The numerical control machine 10 includes a base 11 and receiving seats 12 disposed on opposite sides of the base 11, the forming space 15 is located between the two receiving seats 12, a receiving space 125 is formed in each receiving seat 12, and the receiving space 125 is used for receiving a glass tube. The console 50 includes a base 51, a support column 52 and a console 53, the support column 52 is installed on the base 51, and the console 53 is disposed on the top end of the support column 52. The surface of the control console 53 is an inclined surface 535, and a plurality of control buttons 538 are arranged on the inclined surface 535. The control buttons 538 are all cylindrical, and the inclined surface 535 is further provided with an integrated control button 538.

By providing the mounting frame 16, the mounting of the rotary drive member 21 is facilitated. The heating assembly 30 can be used to heat the opposite sides of the glass tube more conveniently. The gas quantity of the heating structure 35 can be monitored more conveniently by the flow meter, and the heating quantity of the heating structure 35 is controlled. Through the arrangement of the connecting pipe, the vacuum pump 41 can be conveniently utilized to carry out vacuum-pumping operation in the glass pipe. The sealing plug 43 can be used to seal the top end of the rotary core rod 22, thereby facilitating the vacuum pump 41 to perform the vacuum pumping operation on the glass tube. The glass tube or other parts can be received in the receiving space 125 of the receiving seat 12, and the receiving efficiency is improved. The control table 53 can be used to easily control the numerical control machine 10. The angled surface 535 facilitates the installation of the plurality of control buttons 538. With the integrated control button 538, the numerical control machine can be controlled by one key, namely, the following procedures are controlled by one key: rotation of the rotary mandrel 22, heating ignition of the heating assembly 30, and evacuation of the vacuum rod.

Referring to fig. 3 and 4, the top end of the receiving seat 12 is protruded with a mounting arm 18, the mounting arms 18 of the two receiving seats 12 are both located at the top of the forming space 15, the two mounting arms 18 are spaced from each other, and an insertion gap 181 is formed between the two mounting arms 18 for inserting the glass tube. Each of the mounting arms 18 is provided with a sliding groove 185, the sliding groove 185 penetrates through the end surface of the mounting arm 18, and the sliding grooves 185 of the two mounting arms 18 are oppositely arranged and are communicated with the insertion gap 181. Two positioning balls are arranged in each sliding groove 185. The glass tube forming numerical control trimmer 100 with the flow meter further comprises a positioning assembly 60, wherein the positioning assembly 60 comprises a sliding plate 61, two toggle strips 62 and a telescopic button 63, two opposite ends of the sliding plate 61 are respectively inserted into the sliding grooves 185 of the two mounting arms 18 in a sliding manner, two opposite ends of the sliding plate 61 are respectively provided with a positioning recess in a concave manner, and the positioning recesses are used for being matched with the positioning balls to position the sliding plate 61. The two toggle strips 62 are disposed at an interval on one side of the sliding plate 61 and are perpendicular to the sliding plate 61, and the two toggle strips 62 extend toward the forming space 15 and respectively abut against the two heating structures 35. The retractable button 63 is telescopically disposed on the sliding plate 61, a positioning rod 635 protrudes from the bottom of the retractable button 63, and the sealing plug 43 is disposed on the positioning rod 635.

When the positioning assembly 60 is used, the glass tube is inserted into the forming space 15 from the insertion gap 181 and is sleeved and positioned on the rotating core rod 22, the retractable button 63 is pushed laterally to drive the sliding plate 61 to slide laterally, so that the sealing plug 43 is aligned with the top end of the rotating core rod 22, meanwhile, the two toggle strips 62 laterally push the two heating structures 35 to move to the two opposite sides of the glass tube, and the retractable button 63 is pressed to force the sealing plug 43 to be sealed on the top end of the glass tube. By providing the positioning assembly 60, the sealing of the glass tube is facilitated, and the two heating structures 35 are also conveniently aligned with opposite sides of the glass tube.

For example, in order to facilitate preheating of the rotary core rod 22 to prevent the cold glass from being heated by the two heating structures 35 and being continuously heated to a high temperature and then exploding, the mounting frame 16 is further provided with a preheating member (not shown) for preheating the rotary core rod 22 to enable the glass tube sleeve to be arranged on the rotary core rod 22 and preheated to a certain temperature, and then the two heating structures 35 are used for heating the glass tube to prevent the glass tube from exploding. For example, in order to improve the heating uniformity of the glass tube, please refer to fig. 1 again, a U-shaped groove 128 is concavely provided on the surface of each receptacle 12 facing the forming space 15, the U-shaped groove 128 includes a first sliding groove 1281, a second sliding groove 1282 and an arc-shaped connecting groove 1283, and the first sliding groove 1281 and the second sliding groove 1282 are parallel to each other and both extend in the vertical direction. The arc connecting groove 1283 is located at the top end of the first sliding groove 1281, and the two opposite ends of the arc connecting groove 1283 are respectively connected with the first sliding groove 1281 and the second sliding groove 1282. Each heating structure 35 includes a flame projecting head 351, a telescopic guide rod 352 and a reciprocating cylinder (not shown), the flame projecting heads 351 of the two heating structures 35 are respectively arranged at two opposite sides of the glass tube, one end of the telescopic guide rod 352 is connected with the flame projecting head 351, the other end is slidably arranged in the U-shaped groove 128, the reciprocating cylinder is arranged at the bottom surface of the forming space 15 and is connected with the telescopic guide rod 352 through a pulling structure (not shown), the telescopic guide rod 352 is connected with the mounting arm 18 through a tension spring, the pulling structure includes a pulling rod and an elastic ferrule, the pulling rod is connected with the reciprocating cylinder, the elastic ferrule is arranged at the end of the pulling rod, and the telescopic guide rod 352 is arranged in the elastic ferrule in a penetrating way. In the process of heating the glass tube, the reciprocating cylinder pulls the telescopic guide rod 352 to move up and down by overcoming the tension of the tension spring, so that the two flame throwers 351 can heat the glass tube up and down in a reciprocating manner, and the heating uniformity of the glass tube is improved.

Due to the existence of the preheating piece, the temperature of the bottom of the rotating mandrel 22 is slightly higher than that of the top, in order to improve the heating uniformity of the glass tube, two first guide rods 13 and two second guide rods 14 are arranged on the bottom surface of the forming space 15, the two first guide rods 13 are straight rods and are respectively arranged on two opposite sides of the rotating mandrel 22, and the two first guide rods 13 are both obliquely arranged relative to the rotating mandrel 22. The distance between the first guide bar 13 and the rotary mandrel 22 increases gradually in the direction toward the bottom surface of the molding space 15. The two flame spray heads 351 are slidably disposed through the two first guide rods 13. When the reciprocating cylinder drives the telescopic guide rod 352 to descend, the distance between the two flame spray heads 351 is gradually increased, and the length of the telescopic guide rod 352 is gradually reduced in the process of descending. Finally, the bottom of the glass tube receives more heat from the rotating core rod 22 and receives less heat from the two heating structures 35, so that the heating uniformity of the glass tube is improved.

In order to adapt to the heating condition of glass tubes of different models and improve the uniformity of the glass tubes, the two second guide rods 14 are respectively arranged on one sides of the two first guide rods 13, the second guide rods 14 are arranged at intervals with the corresponding first guide rods 13, the two second guide rods 14 are arc-shaped rods and are respectively arranged on two opposite sides of the rotating mandril 22, and the two second guide rods 14 are obliquely arranged relative to the rotating mandril 22. The connecting line of the two first guide rods 13 is located on the connecting line of the two first sliding grooves 1281, and the connecting line of the two second guide rods 14 is located on the connecting line of the two second sliding grooves 1282. One side of the flame-projecting head 351 of each of the two heating structures 35 is provided with a guiding structure 355, and each of the two guiding structures 355 is used for cooperating with the two second guiding rods 14, so as to guide the flame-projecting head 351 to be slidably clamped on the two second guiding rods 14 after laterally separating from the two first guiding rods 13. The two second guide bars 14, which are curved, enable a better adjustment of the distance of the two heating structures 35 from the rotating mandrel 22.

A guide rail 157 is further disposed on the bottom surface of the molding space 15, and the mounting frame 16 is slidably disposed on the guide rail 157. The sliding plate 61 is further provided with a pushing and abutting rod (not shown), the pushing and abutting rod is located in the middle of the two toggle strips 62, one end of the pushing and abutting rod extends to the side of the mounting frame 16, and the pushing and abutting rod is used for pushing and abutting the mounting frame 16 to move along the guide rail 157. When the two second guide rods 14 are needed for guiding, the sliding plate 61 is pushed transversely, so that the two flame throwers 351 pass over the two first guide rods 13 from the top ends of the two first guide rods 13, and the guide structures on the two flame throwers 351 are aligned with and slidably clamped on the two second guide rods 14 respectively. At this time, the pushing rod pushes the mounting frame 16 to drive the rotating mandrel 22 to move laterally, so that the rotating mandrel 22 is located between the two second sliding grooves 1282, and at this time, the sliding plate 61 is positioned. The reciprocating cylinder drives the two flame projecting heads 351 to move up and down along the two second guide bars 14.

For example, in order to avoid burning the reciprocating cylinder, etc., arc-shaped fire blocking pieces 168 are respectively provided at opposite sides of the mounting frame 16, the arc-shaped fire blocking pieces 168 have elasticity, the top portions of the arc-shaped fire blocking pieces 168 are connected to the bottom portions of the corresponding fire ejecting heads 351, a pulling rope is provided at the middle portion of the arc-shaped fire blocking pieces 168, the end portions of the pulling rope are connected to the bottom surface of the forming space 15, and one end of the pulling rope, which is far from the arc-shaped fire blocking pieces 168, extends in a direction far from the mounting frame 16, so that the arc-shaped fire blocking pieces 168 can be pulled to be kept away from the rotating mandrel 22, leaving a moving space for the forming operation of the glass tube.

The present embodiment is only for explaining the present invention, and it is not limited to the present invention, and those skilled in the art can make modifications of the present embodiment without inventive contribution as needed after reading the present specification, but all of them are protected by patent law within the scope of the claims of the present invention.

Claims (6)

1. The utility model provides a glass pipe shaping numerical control trimmer with flowmeter which characterized in that: the forming device comprises a numerical control machine table, a forming assembly, a heating assembly, a vacuum assembly and a control table, wherein a forming space is formed in the numerical control machine table, the forming assembly comprises a rotary driving piece and a rotary mandril, the rotary driving piece is arranged at the bottom of the forming space, the rotary mandril is arranged on the rotary driving piece and used for sleeving and installing a glass tube, the heating assembly is movably arranged on the side wall of the forming space and used for heating the glass tube, the vacuum assembly is arranged adjacent to the rotary driving piece and used for vacuumizing the glass tube, the control table is arranged adjacent to the numerical control machine table, and the rotary driving piece, the heating assembly and the vacuum assembly are electrically connected with the control table;

the numerical control machine comprises a base and accommodating seats arranged on two opposite sides of the base, the forming space is positioned between the two accommodating seats, an accommodating space is formed in each accommodating seat, and the accommodating space is used for accommodating a glass tube; the top end of each accommodating seat transversely protrudes with a mounting arm, the mounting arms of the two accommodating seats are both positioned at the top of the forming space, the two mounting arms are arranged at intervals, and an insertion gap is formed between the two mounting arms for inserting the glass tube;

the heating assembly comprises two heating structures which are oppositely arranged, and the rotary mandrel is positioned between the two heating structures;

the positioning assembly comprises a sliding plate, two shifting strips and a telescopic button, the two opposite ends of the sliding plate are respectively inserted into the sliding grooves of the two mounting arms in a sliding manner, the two opposite ends of the sliding plate are respectively provided with a positioning recess in a concave manner, the positioning recesses are used for being matched with positioning balls to position the sliding plate, the two shifting strips are arranged on one side of the sliding plate at intervals and are both vertical to the sliding plate, and the two shifting strips extend towards the forming space and are respectively abutted against the two heating structures;

the bottom wall of the forming space is provided with an installation frame, and the rotary driving piece is arranged in the installation frame;

the mounting frame is further provided with a preheating piece, the preheating piece is used for preheating the rotary core rod, a U-shaped groove is concavely arranged on the surface, facing the forming space, of each accommodating seat, the U-shaped groove comprises a first sliding groove, a second sliding groove and an arc-shaped connecting groove, and the first sliding groove and the second sliding groove are parallel to each other and extend in the vertical direction; the arc connecting groove is positioned at the top end of the first sliding groove, and two opposite ends of the arc connecting groove are respectively connected with the first sliding groove and the second sliding groove; each heating structure comprises a flame-throwing head, a telescopic guide rod and a reciprocating cylinder, the flame-throwing heads of the two heating structures are respectively arranged on two opposite sides of the glass tube, one end of the telescopic guide rod is connected with the flame-throwing head, the other end of the telescopic guide rod is slidably arranged in the U-shaped groove, the reciprocating cylinder is arranged on the bottom surface of the forming space and is connected with the telescopic guide rod through a pulling structure, the telescopic guide rod is connected to the mounting arm through a tension spring, the pulling structure comprises a pulling rod and an elastic ferrule, the pulling rod is connected to the reciprocating cylinder, the elastic ferrule is mounted at the end part of the pulling rod, and the telescopic guide rod penetrates through the elastic ferrule;

two first guide rods are arranged on the bottom surface of the forming space, are straight rods and are respectively arranged on two opposite sides of the rotating mandrel, and are obliquely arranged relative to the rotating mandrel; the distance between the first guide rod and the rotating mandrel is gradually increased along the direction towards the bottom surface of the forming space; the two flame-throwing heads are slidably arranged on the two first guide rods in a penetrating way;

each heating structure is connected with a fuel gas source through a gas pipe, and a flow meter is installed on the gas pipe.

2. The numerical control shaper for glass tube forming with flow meter according to claim 1, wherein: the vacuum assembly comprises a vacuum pump and a connecting pipe, the vacuum pump is installed in the installation frame, one end of the connecting pipe is connected with the vacuum pump, and the other end of the connecting pipe extends to the bottom of the rotary mandrel.

3. The numerical control shaper for glass tube forming with flow meter according to claim 2, wherein: the vacuum assembly further comprises a sealing plug, and the sealing plug is arranged at the top end of the rotary core rod and used for sealing the top end of the glass tube.

4. The numerical control shaper for glass tube forming with flow meter according to claim 3, wherein: the control cabinet comprises a base, a support column and a control table top, wherein the support column is installed on the base, and the control table top is arranged at the top end of the support column.

5. The numerical control shaper for glass tube forming with flow meter according to claim 4, wherein: the surface of control mesa is the inclined plane, be provided with a plurality of control button on the inclined plane.

6. The numerical control shaper for glass tube forming with flow meter according to claim 5, wherein: the control buttons are cylindrical, and integrated control buttons are further arranged on the inclined surface.

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