JP2005329524A - Wire electric discharge machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent any increase in running cost by inhibiting pressurized liquid from being injected upward from the upper end of a guide mechanism when the pressurized liquid causes a reverse flow upward in a wire electric discharge machine. <P>SOLUTION: This wire electric discharge machine includes: a feed roller for feeding a wire electrode to a machining area; a wire detection means for detecting the wire electrode fed by the feed roller; a guide mechanism having first and second orifices disposed at a space vertically and guiding the wire electrode to the machining area; a liquid supply means for supplying pressurized liquid to a liquid passage on the downstream side in the wire electrode moving direction from the second orifice of the guide mechanism; a recovery part roller for transporting the wire electrode in the vicinity of an inlet of the wire electrode recovery part; and a recovery part wire detection means for detecting the arrival of the tip of wire at the recovery part. The second orifice is disposed below the first orifice, and the diameter of the liquid separation hole of the second orifice is set larger than the height of the liquid separation hole. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an improved wire electrode guide mechanism in which a wire electrode can be easily fed and supplied to a processing region of a workpiece in connection with a wire electric discharge machine.

  Usually, in wire electric discharge machining, the wire electrode delivered from the wire bobbin is subjected to electric discharge machining with a workpiece (workpiece) through a tension device, a guide mechanism, and an upper guide, and then a lower guide and a feed roller. It is collected in a collection box through a collection unit roller. Such wire electrodes are usually thin with a diameter of about 0.05 mm to 0.3 mm. When a machining discharge pulse is applied between the wire electrode and the workpiece to drill a hole with a complicated cross-sectional shape, after machining of one workpiece is completed, before machining the next workpiece, The wire electrode is forcibly cut once, and a connection work for supplying the new line portion to the upper guide again is required.

  Further, during wire electric discharge machining, the wire electrode may be disconnected due to an abnormal situation such as the concentration of electric discharge within a limited range in the small gap between the wire electrode and the workpiece. Even in that case, a new wire portion of the wire electrode must be supplied to the upper guide.

  As a wire electrode supply device for quickly performing this connection work, for example, in Patent Document 1, a wire electrode guide mechanism is composed of a pipe body and a connecting pipe attached to the lower end thereof. An inverted conical first guide provided at the center of the upper end, a cavity provided subsequently thereto, a compressed air jet provided below the cavity, and provided below the jet An inverted conical second guide, a jet nozzle which is a liquid supply means for ejecting pressurized liquid provided subsequently, and a connecting pipe provided below the first guide, A configuration is disclosed in which the second guide, the jet nozzle, and the connecting pipe are electrically insulated from the pipe body.

According to this configuration, during electric discharge machining, the pressurized liquid is always supplied from the pressurized liquid inlet to the guide mechanism, and the liquid flows from the connecting pipe to the upper guide below the connection pipe. The wire electrode always has an effect that it does not escape from the upper guide by the thrust of the liquid.
Japanese Patent Laid-Open No. 5-92321

  However, according to the above-described conventional configuration, the pressurized liquid flows backward from the jet nozzle and is ejected from the upper end of the pipe body through the second guide, the cavity, and the first guide, and the water droplets are disposed above it. In order to prevent these parts from malfunctioning or becoming unusable by adhering to parts such as wire electrode sensors, a configuration is adopted in which compressed air is supplied from between the second guide and the cavity. ing.

  Therefore, since equipment such as an apparatus for generating compressed air and a supply pipe are required as an energy source, the structure of the wire electric discharge machine becomes complicated, the production cost increases, and the running cost also increases. There was a problem.

  An object of the present invention is to provide a device that does not eject upward from the upper end of a guide mechanism when a pressurized liquid flows back upward in a wire electric discharge machine, simplifying the configuration, and not increasing running costs. Such as providing a device.

  The wire electric discharge machine according to claim 1 includes a feed roller for feeding the wire electrode toward the machining area, a wire detection means for detecting the wire electrode fed by the feed roller, and first and second spaced apart from each other. A guide mechanism having an orifice therein for guiding the wire electrode toward the machining region, a liquid supply means for supplying pressurized liquid to a liquid passage downstream of the second orifice of the guide mechanism in the wire electrode movement direction, and a wire In a wire electric discharge machine having a collection unit roller that conveys a wire electrode in the vicinity of the entrance of the electrode collection unit and a collection unit wire detection unit that detects that the tip of the wire has reached the collection unit, the second orifice has a first orifice The liquid separation hole is disposed below the orifice, and the diameter of the liquid separation hole of the second orifice is formed larger than the height of the liquid separation hole.

  Since the diameter of the liquid separation hole of the second orifice is formed larger than the height of the liquid separation hole, when the pressurized liquid supplied by the liquid supply means flows backward toward the first orifice, the flow velocity of the liquid is weakened. And diffuses along the inner wall of the second orifice and adheres to the inner peripheral surface of the guide passage located between the first and second orifices. As a result, it is not ejected upward from the first orifice.

  According to a second aspect of the present invention, there is provided the wire electric discharge machine according to the first aspect of the present invention, further comprising control means for operating the liquid supply means when the wire electrode is passed through the movement path.

  According to a third aspect of the present invention, there is provided the wire electric discharge machine according to the first or second aspect, further comprising a feed amount detecting means for detecting the wire feed amount, and the control means includes the feed amount detected by the feed amount detecting means and the wire detection means. Based on the detection signal, the liquid supply means is operated before the wire electrode passes through the first orifice.

  According to a fourth aspect of the present invention, there is provided a liquid supply means control method for a wire electric discharge machine, comprising: a guide mechanism having first and second orifices spaced apart from each other and guiding a wire electrode toward a machining area; In a method for controlling the liquid supply means in a wire electric discharge machine having a liquid supply means for supplying pressurized liquid to a liquid passage downstream of the mechanism in the wire electrode movement direction from the second orifice of the mechanism, Forming a diameter of the liquid separation hole of the second orifice disposed below the height of the liquid separation hole and starting the operation of the liquid supply means when the wire electrode is passed through the movement path thereof. Features. Due to the above-described features, substantially the same operation as that of the first aspect can be obtained, and the wire electrode can be smoothly fed into the processing region by the liquid pressure of the liquid.

According to the first aspect of the invention, since the diameter of the liquid separation hole of the second orifice is formed larger than the height of the liquid separation hole, the pressurized liquid supplied by the liquid supply means flows backward toward the first orifice. In some cases, the flow rate of the liquid is weakened, diffuses along the inner wall of the second orifice, and adheres to the inner peripheral surface of the guide passage located between the first and second orifices. As a result, it is not ejected upward from the first orifice.
As a result, the backflowed liquid is not ejected above the first orifice and droplets do not adhere to components such as the wire detection sensor disposed above the guide mechanism, thus preventing malfunction and failure of these components. be able to.
Thus, since it can implement | achieve by changing the shape of the liquid separation hole of a 2nd orifice, it can apply easily, without making the structure of an apparatus complicated, and does not increase cost.

  According to the second aspect of the invention, since the liquid supply means is operated when the wire electrode is passed through the movement path, the wire electrode can be smoothly fed into the processing region by the liquid pressure of the liquid.

  According to the invention of claim 3, since the liquid supply means can be operated before the wire electrode passes through the first orifice, there is a margin in the timing of supplying the pressurized liquid to the guide mechanism.

  According to the invention of claim 4, the diameter of the liquid separation hole of the second orifice arranged below the first orifice is previously formed larger than the height of the liquid separation hole, and the wire electrode is used as the movement path. Since the operation of the liquid supply means is started at the time of passing, substantially the same effect as in claims 1 and 2 can be obtained.

  The wire electric discharge machine of the present invention includes a feed roller that feeds a wire electrode toward the machining area, a wire detection means that detects the wire electrode fed by the feed roller, and first and second orifices that are spaced apart vertically. A guide mechanism for guiding the wire electrode toward the processing region, a liquid supply means for supplying pressurized liquid to a liquid passage downstream of the second orifice of the guide mechanism in the wire electrode movement direction, and a wire electrode In a wire electric discharge machine having a recovery part roller that conveys a wire electrode in the vicinity of the inlet of the recovery part, and recovery part wire detection means that detects that the tip of the wire has reached the recovery part, the second orifice is the first orifice The diameter of the liquid separation hole of the second orifice is formed larger than the height of the liquid separation hole.

Next, a wire electric discharge machine according to an embodiment of the present invention will be described.
As shown in FIG. 1, the wire electric discharge machine 1 supplies a liquid to a main body frame 2, a processing tank 3 in which an insulating liquid is stored and a workpiece W can be fixed in a state where the work W is immersed in the liquid, and the processing tank 3. Processing for moving and driving the XY table 6 and the XY table 6 for moving the processing liquid supply device 4 and the processing tank 3 in the horizontal direction via the work table 5 (independently in the X and Y directions orthogonal to each other in the XY plane). The tank horizontal drive mechanism 7, the wire electrode 8, the wire feed mechanism 11 that feeds the wire electrode 8 from the wire bobbin 9 to the collection box 10, the upper guide 12 and the lower guide 13 that guide the wire electrode 8 in the vicinity of the surface portion of the workpiece W, the upper guide 12, a guide movement drive mechanism 14 capable of moving and moving 12 up and down, a guide mechanism 15 for guiding the wire electrode 8 toward the machining area, a pump 16 for supplying liquid to the guide mechanism 15 under pressure, When the wire electrode 8 is newly supplied or when the wire electrode 8 is disconnected, the automatic connection mechanism 17 for sending the new wire portion of the wire electrode 8 to the guide mechanism 15 and the used wire electrode 8 with a predetermined length And a wire electrode collecting section 18 that is cut and collected.

The main body frame 2 includes a base 19, a column 20 erected on the rear part of the base 19, and an upper arm 21 that extends slightly forward from the upper part of the column 20, and is used at the rear part of the base 19. A collection box 10 for collecting the wire electrode 8 is set so as to be removable, and a wire bobbin 9 around which the wire electrode 8 is wound is rotatably attached to the upper end portion of the column 20.
The fixed side guide 22 of the guide movement drive mechanism 14 is fixed to the front end portion of the upper arm 21, and the case 23 of the automatic connection mechanism 17 is fixed to the front end portion of the fixed side guide 22, and the base 19 and the fixed side guide are fixed. The processing tank 3 is disposed between the case 22 and the case 23. Further, a lower arm 24 extending forward from near the lower portion of the column 20 is inserted from the rear of the machining tank 3 through the opening thereof, and the lower guide 13 is attached to the front end portion of the upper surface of the lower arm 24.

  The processing tank horizontal drive mechanism 7 includes an X-axis drive motor 25 (see FIG. 5) that drives the processing tank 3 to move in the left-right direction (X-axis direction) in FIG. 1, and the processing tank 3 in the front-rear direction (Y-axis direction). It has a Y-axis drive motor 26 (see FIG. 5) that moves. The machining tank 3 can be moved and driven independently by the X-axis drive motor 25 and the Y-axis drive motor 26 in the left-right direction and the front-rear direction via the work table 5, and the workpiece W fixedly set in the machining tank 3. It is possible to relatively move the upper guide 12 and the lower guide 13 in the XY plane.

  The guide movement drive mechanism 14 includes a fixed side guide 22, a guide Z-axis drive motor 27 (see FIG. 5) provided inside the fixed side guide 22, and a bellows-like cover 28 a extending downward from the fixed side guide 22. It has a movable slider 28 provided and a horizontal arm 29 that is fixed to the lower end of the movable slider 28 and extends forward. The upper guide 12 faces the lower guide 13 at the front end of the lower surface of the horizontal arm 29. When attached and the guide Z-axis drive motor 27 is driven, the upper guide 12 is driven to move up and down via the movable slider 28 and the horizontal arm 29.

  The wire feed mechanism 11 includes a feed roller 65 provided on the front side of the wire bobbin 9, a feed roller 66 provided on the side surface of the fixed side guide 22, feed rollers 61 and 62 provided on the automatic connection mechanism 17, A feeding roller 67 provided at the inner front end portion of the arm 24 and a collecting unit roller 68 for conveying the wire electrode 8 provided near the entrance of the wire electrode collecting unit 18 are provided. At least the feed rollers 61, 62, and 65 are configured as drive rollers that are rotationally driven by an electric motor or the like. The wire electrode 8 extending from the wire bobbin 9 is fed toward the processing area by these feed rollers 61, 62, 65, 67. Specifically, it extends downward after being guided by the feed rollers 61, 62, 65, 67, traverses the wire cutter and the wire detection sensor 63, passes through the inside of the guide mechanism 15, reaches the upper guide 12, It is guided by the guide 12 and extends downward, reaches the lower guide 13, is guided, and is guided by the feed roller 67 and the recovery unit roller 68 and sent to the wire electrode recovery unit 18.

  The automatic connection mechanism 17 includes a wire detection sensor 63 that functions as a wire detection means that detects the wire electrode 8 that is sent by the feed rollers 61 and 62 and is disposed inside the case 23. A powder brake for applying tension, a drive motor for rotating the wire electrode 8 clamped by the pinch roller forward and backward in processing and sending it in a predetermined direction, and a defective portion of the wire including the disconnection portion at disconnection A wire cutting device for cutting the wire electrode, a wire feed amount detection encoder 64 functioning as a feed amount detecting means for detecting the feed amount of the wire electrode 8, and an electronic communication device for supplying a pulse current to the wire electrode 8 during electric discharge machining. Etc. The upper end of the outer pipe 33 of the guide mechanism 15 is connected to the lower surface of the case 23, the lower end of the intermediate pipe 35 of the guide mechanism 15 is connected to the front upper end of the horizontal arm 29, and the outer pipe 33 is connected to the intermediate pipe 35. The wire electrode 8 is inserted into these guide mechanisms 15 so as to be movable up and down from the upper side.

  The wire feed amount detection encoder 64 is composed of a disk having a plurality of radial micro slits and a photo interrupter, and the disk is provided so as to rotate integrally with the feed roller 61. By rotating the feed roller 61, the disk of the wire feed amount detection encoder 64 is also rotated by the same amount, and the feed amount of the wire electrode 8 is obtained by counting the number of slits that have passed through the photo interrupter.

The wire electrode recovery unit 18 includes a rotary cutter 69, a fixed blade 70, a recovery box 10,
It has a recovery part wire detection sensor 71 that functions as recovery part wire detection means for detecting that the tip of the wire electrode 8 has reached the wire electrode recovery part 18. The used wire electrode 8 is sent between the rotary cutter 69 and the fixed blade 70 by the wire feed mechanism 11, divided into a predetermined short length by the rotational drive of the rotary cutter 69, and then discharged to the collection box 10. The

Next, the structure of the guide mechanism 15 is demonstrated based on FIG.
The guide mechanism 15 has a guide block 30 in which a first orifice 31 and a second orifice 32 are vertically spaced apart. The guide block 30 includes a first guide block 30a having a first orifice and a second guide block 30b having a second orifice 32, an outer pipe 33, an inner pipe 34, an intermediate pipe 35, and the like. The substantially cylindrical first guide block 30a has a funnel-shaped wire introduction portion 38 formed at the upper end thereof, and a first orifice 31 having a liquid separation hole 31a on the lower end side is fixed to the lower portion of the wire introduction portion 38. ing. The diameter of the liquid separation hole 31a is large enough to allow the wire electrode 8 to be inserted therethrough, and is formed to be about 0.5 mm. The first guide block 30a is pivotally supported by a spherical bearing 36 composed of a spherical inner ring and an outer ring having the same inner spherical surface as its outer peripheral spherical surface. The spherical bearing 36 is supported via a support base 37 made of an electrically insulating material. Is attached to the lower portion of the case 17.

  As shown in FIG. 4, the second orifice 32 is disposed below the first orifice 31, and has a liquid separation hole 32 a similar to the first orifice 31, and the diameter thereof is larger than the height of the liquid separation hole 32 a. It is formed to be large. This is because when the liquid pressurized by the pump 16 (pressurized liquid) flows backward, the flow rate of the liquid is weakened and diffused along the inner wall of the second orifice 32. A female screw portion formed in the upper opening hole 39 of the second guide block 30b is screwed and connected to a male screw portion at the lower end portion of the outer periphery of the first guide block 30a protruding downward from the spherical bearing 36.

  In the second guide block 30b, a mounting block 40 having a guide passage 41 opened on the same axis as the liquid separation hole 31a of the first orifice 31 and a second orifice 32 fixed to the lower end thereof has an upper opening hole 39. It is decorated through. In the lower cavity 43 of the second guide block 30b, an upper part of the vertically long inner pipe 34 is mounted through a thrust stop ring 42 so as not to fall off. Accordingly, the inner pipe 34 and the outer pipe 33 are suspended downward from the second guide block 30b.

  The upper part of the outer pipe 33 is screwed to the outer periphery of the second guide block 30b, and communicates vertically between at least the inner diameter of the outer pipe 33 between the outer pipe 33 and the inner pipe 34. The intermediate pipe 35 is arranged to be movable up and down so as to have a gap that becomes a drainage channel 44 that opens at the bottom. A slider block 45 made of synthetic resin or the like screwed onto the upper end portion of the intermediate pipe 35 is slidably fitted on the outer periphery of the inner pipe 34. A gap is also formed between the inner diameter of the intermediate pipe 35 and the outer diameter of the inner pipe 34.

  The lower cavity 43 between the lower end of the second guide orifice 32 and the upper end of the inner pipe 34 communicates with a pressurized liquid inlet 46 provided on the side surface of the second guide block 30b. The first guide path leads the pressurized liquid to the inner diameter portion of the inner pipe 34, that is, the wire passage 47 through which the wire electrode 8 is inserted. Further, in the second guide block 30 b, a second flow path 49 having a large passage section so as to communicate with the lower surface of the first orifice 31, the upper surface of the mounting block 40, and the drainage channel 44 is provided on the outer peripheral side of the mounting block 40. To form. As a result, when the pressurized liquid guided to the lower cavity 43 is directed toward the first orifice 31 via the second orifice 32 and the guide passage 41, the flow resistance is lower than that of the liquid separation hole of the first orifice 31. The liquid flows into the second flow path 49, and the liquid is allowed to leak from the opening 44 a at the lower end of the outer pipe 33 through the drainage path 44.

  The suction block 50 is attached to the lower end of the intermediate pipe 35 by screwing or the like, the lower body 50a of the suction block 50 is connected to the lower spherical bearing 51, and the upper guide is connected to the outer peripheral support 52 of the lower spherical bearing 51. 12 is arranged. The suction block 50 (lower body 50 a) is formed with passages 53, 53 a that communicate with the lower end of the inner pipe 34 and communicate with the guide orifice 12 a of the upper guide 11 on the same axis, and branch from the passage 53. Thus, a suction passage 55 communicating with the suction cap 54 is provided. Then, by connecting the supply pipe of the pump 16 to the introduction base 46 and connecting the suction pipe of the pump 16 to the suction base 54, the liquid passage on the downstream side in the wire electrode moving direction from the second orifice 32 of the guide mechanism 15. Pressurized liquid is supplied to a wire passage 47.

  Next, the control system of the wire electric discharge machine 1 will be described with reference to FIG. The control device C of the wire electric discharge machine 1 includes a microcomputer including a CPU 74, a ROM 75, and a RAM 76, an input interface 72, and an output interface 73. The input interface 72 includes an operation panel 77 and a recovery unit wire detection sensor 71. The wire detection sensor 63 and the wire feed amount detection encoder 64 are electrically connected.

  The output interface 73 includes a display controller 78 for driving the display 79, X-axis drive motor 25, Y-axis drive motor 26, guide Z-axis drive motor 27, and drive circuits 80, 81, 82 for driving the pump 16. , 84, arc discharge circuit 83, and wire feed mechanism 11 are electrically connected. Although not shown, a drive circuit for driving the wire cutting device and the actuator of the wire feed mechanism 11 is electrically connected to the output interface 73.

The ROM 75 stores an electric discharge machining program, a data input setting control program for inputting and setting electric discharge machining data of the electric discharge machining program, a control program for sending the wire electrode 8 to the machining area, and the like. When the CPU 74 reads the control program stored in the ROM 75 and cooperates with hardware resources, the feed detected by the wire feed amount detection encoder 64 when the wire electrode 8 is passed through the guide mechanism 15 as the movement path. Based on the amount and the detection signals of the wire detection sensor 63 and the recovery part wire detection sensor 71 which is the recovery part wire detection means, the pump 16 is started to operate before the tip of the wire electrode 8 passes through the first orifice 31. At the same time, it functions as a control means for stopping the operation of the pump 16 when the tip of the wire electrode 8 reaches the wire electrode recovery section 18.
The RAM 76 has a function as a storage unit that stores the distance from the position where the wire electrode 8 is detected by the wire detection sensor 63 to the position where the orifice is provided.

  Next, control performed when the wire electrode 8 is fed into the machining area will be described based on the flowchart of FIG. In the figure, Si (i = 1, 2,...) Indicates each step. At the start of wire electric discharge machining, after the work W is placed on the work table 5, the operation panel 77 is operated while viewing the screen displayed on the display 79, so that the movement to the machining initial position and the upper guide 12 are performed. Align to the connection position of. The wire feed mechanism 11 is operated (S1), the feed of the wire electrode 8 is started, and the count value of the wire feed amount detection encoder 64 is initialized. The wire electrode 8 extending from the wire bobbin 9 is guided by the feed rollers 61, 62, 65 and then extends downward. When the wire electrode 8 crosses the wire detection sensor 63, the wire detection sensor 63 is turned on (S2; Yes), and the wire feed amount. The detection encoder 64 counts the number of slits that have passed through the photo interrupter due to the rotation of the feed roller 61 (S3). In the RAM 76, the distance from the wire detection sensor 63 to the front side at the position of the first orifice 31 of the guide mechanism 15 is stored in advance as a predetermined count value. When the number of slits being counted reaches the predetermined count value (S4; Yes), that is, from the position where the wire electrode 8 is detected by the wire detection sensor 63 until the wire feed amount detection encoder 64 detects it. When the wire feed amount coincides with the distance stored in the RAM 76, it is detected that the wire electrode is before passing through the first orifice 31, and the pump 16 is operated (S5). Supply pressurized liquid at a flow rate of 2 liters.

  As shown in FIG. 7, since the diameter of the liquid separation hole 32a of the second orifice 32 is formed to be larger than the height of the separation hole, when the liquid flows backward immediately after the start of supply, the The flow velocity of the liquid is weakened, diffuses along the inverted conical inner wall of the second orifice 32, and adheres to the inner peripheral surface of the guide passage located between the first orifice and the second orifice. The liquid that reaches the vicinity of the first orifice 31 is not ejected upward from the first orifice 31 and flows to the second flow path 49 having a small flow resistance.

  After the wire electrode 8 passes through the guide mechanism 15 and reaches the lower guide 13, the wire electrode 8 is sent to the wire electrode recovery unit 18 by the feed rollers 67 and 68 and passes through the recovery unit wire detection sensor 71. The sensor 71 is turned on (S6; Yes). Then, the wire feed mechanism 11 and the pump 16 are stopped (S7).

Next, a modified example in which the above embodiment is partially modified will be described.
1) The second orifice 32 may be formed so that the diameter of the liquid separation hole 32a is larger than the height of the liquid separation hole 32a as shown in FIG. 4, for example, as shown in FIG. The lower part of 32 may be tapered.
2) In addition, those skilled in the art can implement the present invention in various forms with various modifications, and the present invention includes such various modifications.

  The present invention can be applied to a wire electric discharge machine that performs electric discharge machining on a workpiece.

1 is a side view of a wire electric discharge machine according to an embodiment of the present invention. It is a partially cutaway sectional view of a guide mechanism. It is upper part principal part sectional drawing of a guide mechanism. It is upper part principal part sectional drawing of a guide mechanism. It is a block diagram which shows the control system of a wire electric discharge machine. It is a flowchart of the control program which controls a liquid supply means. It is upper part principal part sectional drawing of a guide mechanism (a wire electrode is a position of a 1st orifice). FIG. 5 is a diagram corresponding to FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Wire electric discharge machine 8 Wire electrode 15 Guide mechanism 16 Liquid supply means 18 Wire electrode collection | recovery part 31 1st orifice 32 2nd orifice 32a Liquid separation hole 61, 62, 65, 67 Feed roller 63 Wire detection means 64 Feed amount detection means 68 Recovery Unit Roller 71 Recovery Unit Wire Detection Unit 76 Storage Unit C Control Unit

Claims (4)

A wire roller that feeds the wire electrode toward the machining area, a wire detection means that detects the wire electrode that is fed by the feed roller, and first and second orifices that are spaced apart from each other inside are machined. A guide mechanism for guiding the region toward the region, a liquid supply means for supplying pressurized liquid to a liquid passage downstream of the second orifice of the guide mechanism in the wire electrode movement direction, and a wire electrode in the vicinity of the inlet of the wire electrode recovery section In a wire electric discharge machine having a collection unit roller to convey and a collection unit wire detection means for detecting that the tip of the wire has reached the collection unit,
The wire orifice machine is characterized in that the second orifice is disposed below the first orifice, and the diameter of the liquid separation hole of the second orifice is formed larger than the height of the liquid separation hole.   The wire electric discharge machine according to claim 1, further comprising a control unit that operates a liquid supply unit when the wire electrode is passed through the moving path. A feed amount detection means for detecting the wire feed amount is provided,
The control means operates the liquid supply means before the wire electrode passes through the first orifice, based on the feed amount detected by the feed amount detection means and the detection signal of the wire detection means. Item 3. An electric discharge machine according to item 1 or 2. A guide mechanism that has first and second orifices spaced apart from each other inside and guides the wire electrode toward the processing region, and a liquid passage downstream of the guide mechanism in the wire electrode moving direction from the second orifice In a method of controlling the liquid supply means in a wire electric discharge machine having a liquid supply means for supplying pressurized liquid to
In advance, the diameter of the liquid separation hole of the second orifice disposed below the first orifice is formed larger than the height of the liquid separation hole,
A liquid supply means control method for a wire electric discharge machine, wherein the operation of the liquid supply means is started when the wire electrode passes through the movement path.