KR950005293Y1 - Hydrauric devices of macinery - Google Patents

Abstract

No content.

Description

Molding hydraulics of machine tools

1 is a partial cutaway plan view of the present invention.

2 is a front view of a partial incision of the present invention.

3 is an exploded perspective view of a jack nut power train.

4 is a working state of the wedge by the chain mechanism.

5 is an operational right side view of the wedge.

6 is a power transmission device of the worm and worm gear by the hydraulic motor.

7 is a jack nut power train.

8 is a detailed view of the slide liner bearing.

9 is a fastening state of the wedge holder.

10 is a detailed view of the link (a) is a state diagram fastened to the intermediate wedge, (b) is a front view of the link.

* Explanation of symbols for main parts of the drawings

1: Rear fixing plate 2, 2 ': Mold moving plate

3: mold fixing plate 4: tie rod

5: tie rod sleeve 6: tie rod nut

7, 7 ': jack nut 8, 8': jack screw

9: jack guide 12: sliding linear

13, 28: bracket 15, 15 ': boosting cylinder

16: main cylinder 17: guide

18: rail 20, 20 ': middle wedge

21, 21 ': left wedge 22, 22': right wedge

23: slide linear bearing

25: guide roller 27: sprocket

29: guide holler 30: return spring

31 stud rod 32 worm

33: worm gear 34: hydraulic motor

36, 36 ', 36-1: Link 37: Ring

38: friction bearing 39: chain

40: engaging portion 41: stopper

45: slide linear bearing ball

46: cage

The present invention relates to a mold clamping hydraulic device of a working machine such as an injection molding machine or a hydraulic press, and more particularly, by moving the mold moving plate integrally to the mold fixing plate by the main cylinder and then operating the medium pressure cylinder. Is temporarily inserted between the left and right wedges of the wedge located in the central part of this paper, and the force is supplied to the mold through the jack nut and the jack screw to temporarily transmit and maintain the strong force to the mold to be processed. It relates to a hydraulic device.

In general, in the direct pressure hydraulic device such as an injection molding machine or a hydraulic press, in order to generate a large force during the clamping, a double or multiple hydraulic chambers are configured so that the sequential operation can be performed. The cylinder was enlarged, and therefore, it was pointed out as a significant increase in the manufacturing cost.

In addition, there is a utility model publication No. 90-7406 as the prior art, which is moved to the position close to the mold by the micro-hydraulic supplied to the piston along the inner surface of the cylinder guide tube fixed side, and then screw the outer peripheral surface of the cylinder body The compression nut inserted in the groove is transferred and fastened as a stopper, and the fixed cylinder and the centered cylinder are temporarily operated to provide a powerful force to the mold to be processed, but this is a screw groove on the outer peripheral surface of the cylinder body. Forming and using the inner surface as a cylinder and inserting it into the cylinder guide tube again caused the manufacturing cost increase due to the manufacturing difficulties.

The present invention was devised to solve the above-mentioned shortcomings. The main cylinder is moved to the mold fixing plate of the other side by moving the jack nut and jack screw which are integrally formed with the mold moving plate with one side mold installed using the main cylinder. By operating the intermediate wedge between the right wedge and the left wedge of the wedge to transmit and maintain a strong clamping force through the jack nut and jack screw to form a complete workpiece.

In addition, the present invention solves the manufacturing difficulties shown in the prior art and by placing a tie rod sleeve on the outer circumference of the tie rod as an auxiliary device for achieving the purpose, the tie rod by the stress generated from the strong clamping force applied from the heavy-pressure cylinder Is prevented from obtaining precision processed products and prevents breakage or cracking of machine tools, and the jack screws and jack nuts that are integrally formed with the mold moving board when the mold is separated to remove the processed products Guide jack guides are used to guide precise movement and prevent deformation due to deflection so that they can be used to form precise workpieces.

In addition, according to the thickness of the mold and the size of the workpiece, the jack nut adjustment device was installed to adjust the jack nut according to the separation distance between the mold moving plate and the mold fixing plate to form a precise processed product.

The present invention made of the above configuration solves the difficulty of securing the space in the workplace due to the enlargement of the hydraulic apparatus as in the prior art, and solves the manufacturing difficulties shown in the prior art, as well as the peripheral device to produce a precise processed product. It is a useful design that enables the miniaturization of hydraulic devices, reduction of manufacturing costs, and production of precision processed products.

Hereinafter, described in detail according to an embodiment of the accompanying drawings of the present invention as follows.

Referring to the power transmission unit by the main cylinder in FIG. 1, a plurality of main cylinders 16 are fixed to the rear fixing plate 1 while the ram 10 is fastened, and the cylinder coupling 11 is a ram ( 10) and the mold moving plate 2, and the mold moving plate 2 is fastened to the jack screw (8), and as a result, the main cylinder (16), the mold moving plate (2), the jack nut (7) ), The jack screw 8 is integrally formed.

Next, referring to the wedge portion of FIG. 2 and FIG. 4, the upper portion and the lower portion are symmetrically configured.

The medium pressure cylinder 15 'attached to the upper flat portion of the rear fixing plate 1 is fastened to the middle wedge 20', and the left wedge 21 'and the right side with the middle wedge 20' interposed therebetween. The wedge 22 'is provided in the left and right sides of the slide liner bearing 23 which has the structure of a roller bearing, and is fastened by the chain 39 to the intermediate wedge 20'. In addition, a compression spring 19 is inserted into the left wedge 21 'and the right wedge 22', respectively, and is fastened to the medium pressure cylinder 15 'together with the spring pusher 14. The wedge holder 29 integrally connects the left wedge 21 'and the right wedge 22' to always tighten the left wedge 21 'and the right wedge 22' by the return spring 30. The chain 39 is hung on the sprocket 27 which is fastened by the bracket 28 to the upper side and the lower side of the rear fixing plate 1, respectively. This chain mechanism is composed of two sets of upper and lower parts on the left and right sides of the present invention.

3, 6, and 7, the jack nut 7 power transmission unit is shown by the hydraulic motor 34 and the worm 32 being driven by the key 43 and the sleeve 42 on the shaft 44. Is fastened in a conventional manner, one side of the handle 35 is fastened to the shaft 44 and the worm 32 is connected to the worm gear 33. In addition, the worm gear 33 is engaged with the friction bearing 38 fixed to the jack screw 8, and at the same time there are six stud rods 31 with the ring 37 having six insertion holes therebetween. It is fastened by a fastening bolt. The rear end of the six stud rods 31 is inserted through six insertion holes formed in the jack nut 7 and fastened in the form of a ring 37 located at the rear end and a ring at the front end, and a friction bearing at the rear end. 38 is fastened to the jack screw 8 by the fastening bolt as described above, and is inserted and fastened to the insertion portion formed in the ring 37 at the rear end. As a result, the worm 32 and the worm gear 33 are rotated by the rotation of the hydraulic motor 34, so that the six stall rods 31 rotate, whereby the jack nut 7 is the jack screw 8 It is possible to move back and forth along the screw groove formed on the outer peripheral surface of the.

Looking at the fastening method of the tie rod 4 in FIG. 1, the tie rod 4 is fastened by the stopper 41 to the mold fixing plate 3, and also by the stopper in the rear fixing plate 1. Securely tighten the entire hydraulic system.

On the outer circumference of the tie rod 4, a tie rod sleeve 5 is placed between the rear fixing plate 1 and the mold fixing plate 3 with the tie rod 4 at the inner circumference and the tie rod sleeve 5 ) Is also configured to have a role of a guide for moving the mold moving plate 2 by the slide bush 26.

In FIG. 2, the jack guide 9-the guide-together with the guide roller 25 located at the rear end of the jack screw 8 in the state of being fastened to the rear fixing plate 1 by the stud bolt 24. Not only does the jack screw (8) allow accurate horizontal movement during the return stroke, but also prevents the droop of the jack screw (8), thereby doubling the production of precision workpieces.

According to the description of each part described the operation principle and order of the present invention as follows.

7 ', 8', 10 ', 15', 20 ', 21', 22 ', 31', 32 ', 36' with "" in the code indicates the return position of each part when the mold is removed. to be. After inserting and fixing the mold to be used for the work in the mold moving plate 2 and the mold fixing plate 3, the ram 10 is advanced by the main cylinder 16 to be integrally fastened with the mold moving plate 2. The jack nut (7 ') and jack screw (8') close to the mold fixing plate (3) for the correct positioning of the jack nut. Comes to the position of the jack screw (8)-start the hydraulic motor (34), rotate the worm (32) and worm gear (33) to jack jack (7 ') through the stud rod (31) jack screw (8) By moving along the screw groove of the), it moves to the position of the jack nut 7 and sets it so that it is in a position suitable for the specification of the mold and the workpiece. The handle 35 may be used for more accurate positioning.

When the jack nut (7) is positioned, the gap between the rear fixing plate (1) and the jack nut (7) forms a gap enough to close the wedge, and then the intermediate wedge (20 ') is operated by the operation of the medium pressure cylinder (15'). Is first lowered to be placed in the closed state, the left wedge 21 'is the right wedge 22' is the intermediate wedge 20 by the spring pusher 14 and the compression spring 19 attached to each wedge At the same time as the descent movement will be.

At this time, the left wedge 21 and the right wedge 22 of the lower part of the wedge are symmetrical simultaneously with the same closing operation as the upper part by the medium pressure cylinder 15. (The upper part of Fig. 2 shows an open state.)-The closing action of the wedge portion is simultaneously performed by the intermediate pressure cylinders 15 and 15 'at the same time, and the strong force at this time when the intermediate wedge 20' is completely closed. Is transferred to the mold through the mold moving plate 2 by the jack nut 7 and the jack screw 8 to form a precisely finished mold processed product.

This strong clamping force exerts a tensile force on the tie rods 4 between the rear fixing plate 1 and the mold fixing plate 3, so that the tie rods 4 are slightly tensioned, thereby reducing the precision of the mold product. Let's do it.

To prevent this, the tie rod sleeve 5 is placed on the outer circumference of the tie rod 4 so that the rear fixing plate 1 and the mold fixing plate 3 are secured by the pre-tension of the tie rod 4. Prevent spacing. In addition, the outer circumference of the tie rod sleeve 5 has a slide bush 26 so that the mold moving plate 2 also serves as a guide body.

When the finished product (injection molding) is completed, the return stroke for separating the mold is all performed in the reverse order of the above-described forming of the workpiece. When the jack nut 7 and the jack screw 8 are returned, the jack guide 9 and the guide roller ( 25) prevents the deformation of the jack nut (7) and jack screw (8) by preventing the exact horizontal movement and deflection. As a result, it will play a part in manufacturing precision mold products.

When describing the operation of the wedge part in the return stroke in detail, the intermediate wedge 20, 20 'is opened and returned to the upper and lower parts by the medium pressure cylinder 15, 15', and the intermediate wedge 20, 20 'and the chain The chain 39 rotates as the intermediate wedges 20 and 20 'return by the links 36 and 36' which fasten the 39.

When the links 36 and 36 'come to the position of the link 36' representing the link at the return stroke, the links 36 and 36 'are caught by the catching portion 40, and the left and right wedges 22' and the right wedge 22 'are intermediate. At the same time. In this case, the chain mechanism not only operates symmetrically at the upper and lower portions of the wedge at the same instant, but also has chain mechanisms on the left and right sides, that is, two sets of chain mechanisms are provided at the front and the rear, so that four sprockets are provided. By (27), the upper part and the lower part can not only perform symmetrical simultaneous operation but also maintain the balance of force.

In closing operation, each wedge of the upper and lower parts is guided to the correct position by the chain mechanism. When the return stroke is completed, the right wedges 22 and 22 'and the left wedges 21 and 21' are returned to their original position by the return spring 30 of the wedge holder 29. This completes one cycle.

As described above, the present invention moves the mold to a small main cylinder for forming or pressing a workpiece, and then transfers the mold to the main cylinder with a hydraulic device that completes the shape of the workpiece by transmitting and maintaining a strong clamping force using a booster cylinder. It is a very useful design that solves the shortcomings caused by the enlargement of the conventional hydraulic system and the manufacturing difficulties shown in the prior art Utility Model Publication No. 90-7406 by swiftly moving and double precision machining for the jack guide and tie rod sleeve. .

Claims (3)

In the horizontal movement of the ram 10 installed in the plurality of main cylinders 16 of the rear fixing plate 1 to move the mold moving plate 2, the image is orthogonally symmetrical with the movement direction of the main cylinder 16, A medium pressure cylinder 15 driven vertically at a predetermined position is installed, and a wedge portion for generating a clamping force through the jack nut 7 and the jack screw 8 is formed at the axis end of the central cylinder 15. And installing a tie rod 4 for firmly coupling between the mold fixing plate 3 and the rear fixing plate 1 and simultaneously guiding the mold moving plate 2 sliding on the outer circumferential surface of the tie rod 4. It has a tie rod sleeve (5), which is fixed to the rear fixing plate (1) and the jack nut and the jack screw performs the exact horizontal movement during the return stroke for the mold separation state, and at the same time sag of the jack screw (8) A jack guide 9 and a guide roller 25 for preventing the damage, and the front portion of the jack nut 8 A mold clamping hydraulic system for a machine tool provided with a jack nut power transmission device for positioning the jack nut (8). The left wedge 21 and the right wedge of claim 1, wherein the wedge portion is provided with the slide liner bearing 23 between the intermediate wedge 20 and the intermediate wedge 20 fastened to the intermediate pressure cylinder 15, respectively. And a chain (39) and a sprocket (27) fastened by a link (36) to a portion of the intermediate wedge (20). The jack nut power transmission device according to claim 1, wherein the jack nut power transmission device rotates the worm 32 and the worm gear 33 by a hydraulic motor 34, and transmits the rotational force to the jack nut 7 through the stud rod 31. The clamping hydraulic device of the machine tool, characterized in that configured to.