CN114101560B - Titanium alloy hot forging rapid production equipment - Google Patents

Abstract

The invention provides a titanium alloy hot forging rapid production device, which comprises a supporting device; the supporting device is fixedly connected to the four mounting feet; the rotating shaft on the supporting device is connected with a turnover part; the rotating shaft on the supporting device is connected with a driving part; the top of the supporting device is connected with a feeding part in a sliding way, and the feeding part is fixedly connected with a quenching device; the lifting devices are arranged in two and are respectively and fixedly connected to the top of the supporting device; fixedly connected with forging device between two elevating gear has set up strutting arrangement, has adopted the mode that sets up quenching tank on strutting arrangement, and the integration is seamless to be seted up, and is more stable simultaneously, and is more heat-resisting, and life is longer, and the upset portion that the rotation axis was connected has adopted the upset supporting bench to support the mode simultaneously on supporting platform, realizes rotatory switching, forges more in a flexible way.

Description

Titanium alloy hot forging rapid production equipment

Technical Field

The invention belongs to the technical field of titanium alloy hot forging, and particularly relates to a rapid production device for titanium alloy hot forging.

Background

The titanium alloy refers to various alloy metals made of titanium and other metals, a forging process performed above the metal recrystallization temperature is called hot forging, the hot forging is called hot die forging, the deformed metal flows vigorously during forging, the contact time of the forging and a die is long, and the titanium alloy hot forging is beneficial to the excellent performance of the titanium alloy hot forging, so that the good titanium alloy hot forging rapid production equipment is particularly important.

For example, application number: the CN202011514250.9 relates to an intelligent automatic production system for titanium alloy hot forging, in particular to the technical field of titanium alloy production equipment, and comprises a workbench, wherein a step feeding mechanism, a digital front-end fixed-length mechanism, a digital lifting mechanism, a digital pushing mechanism, a digital heating mechanism and a digital rear-end flexible fixed-length mechanism are fixedly arranged at the top of the workbench through bolts, and the digital front-end fixed-length mechanism is positioned between the step feeding mechanism and the digital heating mechanism; the digital pushing device disclosed by the invention can push the titanium alloy into the heating pipe in the digital heating mechanism, the titanium alloy can locally enter the heating pipe due to the blocking of the digital rear-end flexible fixed-length mechanism, and the heating pipe can locally heat the titanium alloy at the moment so as to reduce the heat resource consumption when the whole titanium alloy is heated, and the local hot forging can also effectively improve the efficiency of a production system on the hot forging of the titanium alloy and improve the practicability of the production system.

Based on the prior art discovery, current titanium alloy hot forging rapid production facility does not set up upset hot forging device, can't forge processing fast after the titanium alloy heats, influence the forging quality when influencing work efficiency, do not set up the material loading guenching unit of integration, consume the manpower, the untimely extremely easy austenitization that leads to the titanium alloy unable better that leads to the titanium alloy physical properties not good of quenching simultaneously, the extremely easy condition that takes place the quenching liquid and is heated the splash in the quenching operation process simultaneously, there is the potential safety hazard, do not set up forging adjusting device, can't adapt to different size forging pieces, inflexible and practical.

Disclosure of Invention

In order to solve the technical problems, the invention provides a titanium alloy hot forging rapid production device, which solves the problems that the existing titanium alloy hot forging rapid production device is not provided with a turnover hot forging device, the titanium alloy cannot be rapidly forged after being heated, the working efficiency is influenced, meanwhile, the forging quality is influenced, an integrated feeding quenching device is not provided, the labor is consumed, meanwhile, the quenching is not timely and extremely easy to cause the titanium alloy to be better austenitized, the physical properties of the titanium alloy are poor, meanwhile, the quenching liquid is extremely easy to be heated and splashed in the quenching operation process, potential safety hazards exist, a forging adjusting device is not provided, and the titanium alloy hot forging rapid production device cannot be suitable for forging blocks of different sizes, and is not flexible and practical.

The invention discloses a titanium alloy hot forging rapid production device, which aims at achieving the following specific technical means:

a titanium alloy hot forging rapid production device comprises a supporting device;

the supporting device is fixedly connected to the four mounting feet; the rotating shaft on the supporting device is connected with a turnover part; the rotating shaft on the supporting device is connected with a driving part; the top of the supporting device is connected with a feeding part in a sliding way, and the feeding part is fixedly connected with a quenching device;

the lifting devices are arranged in two and are respectively and fixedly connected to the top of the supporting device; a forging device is fixedly connected between the two lifting devices.

Further, the supporting device includes:

the support platform is fixedly connected to the four mounting feet;

the quenching tank is arranged on the supporting platform.

Further, the material loading portion still includes:

the reverse gears are provided with two reverse gears; the two reverse gears are connected with the supporting platform through rotating shafts; the two reverse gears are both meshed and connected between the dragging bracket and the feeding bracket;

correcting the board, correcting the board and being equipped with two, two correcting the board and respectively fixed connection drag support and material loading support.

Further, the lifting device includes:

the lifting support is fixedly connected to the supporting platform;

the hydraulic cylinder is fixedly connected to the supporting platform;

the lifting block is connected to the lifting support in a sliding manner, and the bottom of the lifting block is fixedly connected to the hydraulic cylinder.

Further, the driving section includes:

the rotating shaft of the driving threaded rod is connected to the supporting platform;

the transmission gear is meshed with the driving threaded rod and fixedly connected to the shaft end of the side face of the overturning supporting table.

Further, the quenching device includes:

the quenching support is fixedly connected to the dragging support;

the alloy material taking rod is connected with the quenching bracket by a rotating shaft; the front side of the alloy material taking rod is provided with a material taking hook;

the two reset shafts are respectively and fixedly connected to the quenching bracket; the two reset shafts are respectively sleeved on two sides of the quenching bracket, and springs are sleeved on the two reset shafts.

Further, the forging apparatus includes:

the forging power hammer is fixedly connected to the two lifting blocks through a bracket;

the flange hammer head is fixedly connected to the bottom of the forging power hammer through a flange.

Further, the turning part includes:

the overturning supporting table is connected with the supporting platform through a rotating shaft; the two sides of the overturning supporting table are arc-shaped structures, and the two sides of the overturning supporting table are attached to the supporting platform;

the two reverse screw rods are respectively fixedly connected to the supporting platform; the two reverse screw rods are provided with reverse threads;

the forging support block is rotationally connected to the two reverse screw rods in a threaded manner.

Further, the material loading portion includes:

the feeding bracket is connected to the supporting platform in a sliding way through a sliding block; racks are arranged on two sides of the feeding bracket;

the dragging bracket is connected to the supporting platform in a sliding way through a sliding block; and racks are arranged on two sides of the dragging bracket.

Further, the turning part further includes:

the heating platform is rotationally connected to the two reverse screw rods through threads;

the heating pipe is provided with a circle of heating pipes which are embedded in the overturning supporting table.

Compared with the prior art, the invention has the following beneficial effects:

1. in this device, supporting device has been set up, the mode of having adopted to set up the quenching groove on strutting arrangement, the seamless mode of seting up of integration, it is more stable simultaneously, it is more heat-resisting, longer service life, the upset portion that the rotation axis connects has adopted the upset brace table to support simultaneously, realize rotatory, the drive portion that the cooperation set up, under the rotatory drive of drive threaded rod, drive gear rotation, and then realize driving the upset brace table rotation, adopt the drive threaded rod to carry out driven mode, drive threaded rod self has spacing effect, can make the upset brace table rotatory more stable, adopt the mode of forging supporting shoe and heating platform independent installation, can make heating platform have certain cooling time, avoid heating platform to receive forging hammering after the heating, influence life, set up the protection heating pipe that independent heating platform can also be better simultaneously, can realize driving supporting shoe and heating platform operation simultaneously through setting up reverse lead screw, the operation is more convenient, the realization that the upset portion that sets up simultaneously can be more quick carries out the titanium alloy piece after the heat treatment, forge effect, and acceleration production efficiency.

2. In this device, the material loading portion has been set up, the material loading portion has adopted the material loading support can realize advancing the removal with the titanium alloy piece, can prevent that the titanium alloy piece from shifting through the correction board that sets up in the removal process, the cooperation is dragging the support, in the material loading support forward propulsion process, under two reverse gear meshing transmissions, realize driving dragging the support and simultaneously the opposite direction removal, ensure that the titanium alloy piece can be centered the entering upset portion of mistake, through setting up the material loading portion, when being cooperated guenching unit can be more convenient for the staff material loading, prevent that the material loading in-process from taking place the scald because of upset portion high temperature, adopt guenching unit simultaneously, realize the mode that the extrusion drove the titanium alloy piece and remove through the alloy extracting rod, quenching efficiency can be improved greatly, quick quenching helps strip alloy inside austenitizing, improve the metal property.

3. In this device, set up elevating gear, the forging device height of quick adjustment that adopts pneumatic cylinder driven elevating block can be convenient for more to obtain more nimble forging height, set up elevating gear that can height-adjusting simultaneously and can realize avoiding influencing the upset portion and overturn the operation, set up elevating gear and can effectively enlarge the holistic forging scope of equipment, the forging device that sets up simultaneously adopts flange joint's flange tup can be convenient for change more, and is more practical.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a schematic view of the bottom structure of the present invention.

Fig. 3 is a cross-sectional view of the internal structure of the present invention.

Fig. 4 is a schematic view of the internal structure of the present invention.

Fig. 5 is a schematic view of the structure of the supporting device of the present invention.

Fig. 6 is a schematic diagram of the structure of the turnover part of the present invention.

Fig. 7 is a schematic view of the bottom structure of the flip portion of the present invention.

Fig. 8 is a schematic view of the turnover part mounting structure of the present invention.

Fig. 9 is a schematic diagram of the structure of the driving unit of the present invention.

Fig. 10 is a schematic view of the structure of the feeding portion of the present invention.

Fig. 11 is a schematic view of the structure of the feeding portion of the present invention.

Fig. 12 is a schematic view of the structure of the quenching apparatus of the invention.

Fig. 13 is a schematic view of the structure of the lifting device of the present invention.

FIG. 14 is a schematic view of the forging apparatus of the present invention.

In the figure, the correspondence between the component names and the drawing numbers is:

1. a support device;

101. a support platform; 102. a quenching tank;

2. a turnover part;

201. turning over the supporting table; 202. a reverse screw rod; 203. forging a supporting block; 204. a heating platform; 205. heating pipes;

3. a driving section;

301. driving a threaded rod; 302. a transmission gear;

4. a feeding part;

401. a feeding bracket; 402. dragging the bracket; 403. a reverse gear; 404. a correction plate;

5. a quenching device;

501. quenching the bracket; 502. an alloy material taking rod; 503. a reset shaft;

6. a lifting device;

601. a lifting bracket; 602. a hydraulic cylinder; 603. a lifting block;

7. a forging device;

701. forging a power hammer; 702. a flange hammer;

8. and (5) installing the ground feet.

Detailed Description

Embodiments of the present invention are described in further detail below with reference to the accompanying drawings and examples. The following examples are illustrative of the invention but are not intended to limit the scope of the invention.

In the description of the present invention, unless otherwise indicated, the meaning of "a plurality" is two or more; the terms "upper," "lower," "left," "right," "inner," "outer," "front," "rear," "head," "tail," and the like are used as an orientation or positional relationship based on that shown in the drawings, merely to facilitate description of the invention and to simplify the description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be construed as limiting the invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless explicitly specified and limited otherwise, the terms "connected," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium. The specific meaning of the above terms in the present invention will be understood in specific cases by those of ordinary skill in the art.

Examples:

as shown in fig. 1 to 14:

the invention provides a titanium alloy hot forging rapid production device, which comprises a supporting device 1; the support device 1 is fixedly connected to the four mounting feet 8; the rotating shaft on the supporting device 1 is connected with a turnover part 2; the supporting device 1 is connected with a driving part 3 by a rotating shaft; the top of the supporting device 1 is connected with a feeding part 4 in a sliding way, and the feeding part 4 is fixedly connected with a quenching device 5; the lifting devices 6 are arranged, two lifting devices 6 are arranged, and the two lifting devices 6 are respectively and fixedly connected to the top of the supporting device 1; a forging device 7 is fixedly connected between the two lifting devices 6.

As shown in fig. 5 to 9, the supporting device 1 includes: the support platform 101, the support platform 101 is fixedly connected to four installation feet 8; the quenching tank 102 is arranged on the supporting platform 101; the inverting part 2 includes: a turnover supporting table 201, wherein the turnover supporting table 201 is connected to the supporting platform 101 in a rotating shaft manner; the two sides of the overturning supporting table 201 are arc-shaped structures, and the two sides of the overturning supporting table 201 are attached to the supporting platform 101; the two reverse screw rods 202 are arranged, and the two reverse screw rods 202 are fixedly connected to the supporting platform 101 respectively; the two reverse screw rods 202 are provided with reverse threads; the forging support block 203, wherein the forging support block 203 is in threaded rotary connection with the two reverse screw rods 202; the inverting part 2 further includes: the heating platform 204, the heating platform 204 is connected to the two reverse screw rods 202 in a threaded rotation manner; the heating pipe 205, the heating pipe 205 is provided with a circle, and the circle of heating pipe 205 is embedded in the overturning supporting table 201; the driving section 3 includes: the driving threaded rod 301, the driving threaded rod 301 is connected to the supporting platform 101 in a rotating shaft manner; the transmission gear 302, the transmission gear 302 meshes in drive threaded rod 301, and drive gear 302 fixed connection has set up strutting arrangement 1 at upset supporting bench 201 side axle head, adopted and set up quenching tank 102 on strutting arrangement 1, the seamless mode of seting up of integration, more stable, simultaneously it is more heat-resistant, life is longer, the upset portion 2 of rotation hub connection has adopted upset supporting bench 201 to support simultaneously on supporting bench 101, realize rotatory, forge more nimble, the drive portion 3 of cooperation setting, under drive threaded rod 301 rotary drive, drive gear 302 rotation, and then realize driving upset supporting bench 201 rotation, adopt drive threaded rod 301 to carry out driven mode, drive threaded rod 301 self has spacing effect, can make upset supporting bench 201 rotation more stable, adopt the mode of forging supporting shoe 203 and heating bench 204 independent installation, can make heating bench 204 have certain cooling time, avoid heating bench 204 to receive after the heating, hammer influences life, simultaneously set up independent heating bench 204 and also can be better protection heating pipe 205, can realize driving simultaneously supporting shoe 203 and heating bench 204 operation, the operation is more convenient and fast, the forging 2 can be realized to forge the production efficiency of operation of setting up simultaneously, and the forging is fast, the forging is convenient and rapid production is more convenient.

As shown in fig. 10 to 12, the feeding portion 4 includes: the feeding support 401 is connected to the supporting platform 101 in a sliding manner through a sliding block; racks are arranged on two sides of the feeding support 401; the dragging bracket 402, the dragging bracket 402 is connected on the supporting platform 101 through a sliding block in a sliding way; and racks are arranged on two sides of the dragging bracket 402; the feeding portion 4 further includes: a reverse gear 403, wherein two reverse gears 403 are provided; the two reverse gears 403 are both connected to the supporting platform 101 in a rotating shaft manner; the two reverse gears 403 are engaged and connected between the dragging bracket 402 and the feeding bracket 401; the correction plates 404, the correction plates 404 are provided with two, and the two correction plates 404 are respectively fixedly connected to the dragging bracket 402 and the feeding bracket 401; the quenching apparatus 5 includes: the quenching bracket 501, the quenching bracket 501 is fixedly connected to the dragging bracket 402; an alloy material taking rod 502, wherein the alloy material taking rod 502 is connected with the quenching bracket 501 in a rotating shaft manner; a material taking hook is arranged on the front side of the alloy material taking rod 502; reset shafts 503, wherein two reset shafts 503 are arranged, and the two reset shafts 503 are respectively fixedly connected to the quenching bracket 501; two reset shafts 503 are respectively sleeved on two sides of the quenching support 501, springs are respectively sleeved on the two reset shafts 503, a feeding part 4 is arranged, the feeding part 4 adopts the feeding support 401 to push and move titanium alloy blocks, the titanium alloy blocks can be prevented from shifting through a correction plate 404 arranged in the moving process, the dragging support 402 is matched, the dragging support 402 is driven to move oppositely simultaneously under the meshing transmission of two reverse gears 403 in the forward pushing process of the feeding support 401, the titanium alloy blocks can enter the turnover part 2 in a centering manner, the feeding part 4 is arranged, the quenching device 5 is matched, the feeding of workers can be facilitated, the scalding caused by the overhigh temperature of the turnover part in the feeding process is prevented, meanwhile, the quenching device 5 is adopted, the titanium alloy blocks are driven to move in an extrusion manner through an alloy material taking rod 502, the quenching efficiency can be greatly improved, the strip alloy can be rapidly quenched to be austenitized, and the metal performance is improved.

As shown in fig. 13 and 14, the lifting device 6 includes: the lifting support 601, the lifting support 601 is fixedly connected to the supporting platform 101; the hydraulic cylinder 602, the hydraulic cylinder 602 is fixedly connected to the supporting platform 101; the lifting block 603, the lifting block 603 is connected to the lifting bracket 601 in a sliding manner, and the bottom of the lifting block 603 is fixedly connected to the hydraulic cylinder 602; the forging device 7 includes: the forging power hammer 701, wherein the forging power hammer 701 is fixedly connected to the two lifting blocks 603 through a bracket; the flange tup 702, flange tup 702 has set up elevating gear 6 through flange fixed connection in forging power hammer 701 bottom, adopt the elevating block 603 of pneumatic cylinder 602 driven can be convenient for more quick adjustment forging device 7 height to obtain more nimble forging height, set up elevating gear 6 that can height-adjusting simultaneously and can realize avoiding influencing upset portion 2 and overturn the operation, set up elevating gear 6 and can effectively enlarge the holistic forging scope of equipment, the forging device 7 that sets up simultaneously adopts flange tup 702 and can be convenient for change more, it is more practical.

In another embodiment, other structures are unchanged, the driving threaded rod 301 can be replaced by an electric threaded rod, bar manpower can be effectively saved by adopting the electric threaded rod, and meanwhile, adjustment is intelligent and accurate.

When in use, the utility model is characterized in that: firstly, four mounting feet 8 on the equipment are mounted on the ground, the equipment can be mounted, firstly, the titanium alloy block needs to be subjected to heat treatment, in the process, the height of a forging power hammer 701 is adjusted through a hydraulic cylinder 602 to avoid obstructing the overturning part 2, the titanium alloy block is placed on a supporting platform 101 at one side of a feeding bracket 401, then the feeding bracket 401 and a dragging bracket 402 are driven to move oppositely by pushing an alloy material taking rod 502 on a quenching device 5, in the process, the titanium alloy block is driven to move in the process, a correction plate 404 can prevent the titanium alloy block from shifting, the feeding bracket 401 and the dragging bracket 402 move oppositely at the same time, the titanium alloy block can enter the overturning part 2 in a centering way, and then, in the prior process, the driving of a driving gear 302 is driven to rotate through a rotary driving threaded rod 301, the heating platform 204 is driven to rotate to the top by driving the overturning supporting table 201 to manually stir to one side of the feeding support 401, then the titanium alloy block can be subjected to heat treatment, after the treatment is finished, the titanium alloy block is ejected by driving the threaded rod 301, at the moment, the driving drives the rotating threaded rod 301 to drive the overturning supporting table 201 to overturn, then the titanium alloy block can be pushed into the forging supporting block 203 again by the feeding support 401, at the moment, the height of the forging power hammer 701 is controlled by the hydraulic cylinder 602, then the forging power hammer 701 is controlled to forge the titanium alloy block through the flange hammer 702, after the forging is finished, the titanium alloy block can be ejected again by driving the threaded rod 301, the alloy material extracting rod 502 is pressed downwards, then the alloy material extracting rod 502 is clamped by the material extracting hook arranged on the front side of the alloy material extracting rod 502 of the spring on the reset shaft 503, then dragging into the quenching tank 102 for quenching, and finally completing the hot forging rapid production process of the titanium alloy.

The embodiments of the invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.

Claims (3)

1. A titanium alloy hot forging rapid production device is characterized in that: comprises a supporting device (1);

the supporting device (1) is fixedly connected to four mounting feet (8); the rotating shaft on the supporting device (1) is connected with a turnover part (2); the rotating shaft on the supporting device (1) is connected with a driving part (3); the top of the supporting device (1) is connected with a feeding part (4) in a sliding way, and the feeding part (4) is fixedly connected with a quenching device (5);

the lifting devices (6) are arranged, and the two lifting devices (6) are respectively and fixedly connected to the top of the supporting device (1); a forging device (7) is fixedly connected between the two lifting devices (6);

the support device (1) comprises:

the support platform (101), the support platform (101) is fixedly connected to four installation feet (8);

the quenching tank (102), the quenching tank (102) is arranged on the supporting platform (101);

the turning part (2) comprises:

the overturning supporting table (201), the rotating shaft of the overturning supporting table (201) is connected to the supporting platform (101); the two sides of the overturning supporting table (201) are arc-shaped structures, and the two sides of the overturning supporting table (201) are attached to the supporting platform (101);

the two reverse screw rods (202) are arranged, and the two reverse screw rods (202) are respectively and fixedly connected to the overturning supporting table (201); the two reverse screw rods (202) are provided with reverse threads;

the forging support block (203), the forging support block (203) is connected to the two reverse screw rods (202) in a threaded rotation manner;

the turning part (2) further includes:

the heating platform (204), the screw thread of the heating platform (204) is connected to two reverse screw rods (202) in a rotating way;

the heating pipe (205), the heating pipe (205) is provided with a circle, and the circle of heating pipe (205) is embedded on the overturning supporting table (201);

the driving unit (3) includes:

the driving threaded rod (301), the rotating shaft of the driving threaded rod (301) is connected to the supporting platform (101);

the transmission gear (302), the transmission gear (302) is meshed with the driving threaded rod (301), and the transmission gear (302) is fixedly connected to the shaft end of the side face of the overturning supporting table (201);

the feeding part (4) comprises:

the feeding support (401), the feeding support (401) is connected on the supporting platform (101) through the sliding block in a sliding way; racks are arranged on two sides of the feeding support (401);

the dragging bracket (402), the dragging bracket (402) is connected on the supporting platform (101) in a sliding way through the sliding block; racks are arranged on two sides of the dragging bracket (402);

the feeding part (4) further comprises:

gears (403), wherein the gears (403) are provided with two gears; the two gears (403) are connected with the supporting platform (101) in a rotating shaft manner; the two gears (403) are both meshed and connected between the dragging bracket (402) and the feeding bracket (401);

the correction plates (404), the correction plates (404) are provided with two, and the two correction plates (404) are respectively fixedly connected to the dragging bracket (402) and the feeding bracket (401);

the quenching device (5) comprises:

the quenching support (501), the quenching support (501) is fixedly connected to the dragging support (402);

an alloy material taking rod (502), wherein the alloy material taking rod (502) is connected with the quenching bracket (501) in a rotating shaft manner; the front side of the alloy material taking rod (502) is provided with a material taking hook;

the two reset shafts (503) are arranged, and the two reset shafts (503) are respectively and fixedly connected to the quenching bracket (501); the two reset shafts (503) are respectively sleeved on the two sides of the quenching bracket (501), and the springs are respectively sleeved on the two reset shafts (503).

2. The titanium alloy hot forging rapid production apparatus as recited in claim 1, wherein: the lifting device (6) comprises:

the lifting support (601), the lifting support (601) is fixedly connected to the supporting platform (101);

the hydraulic cylinder (602), the hydraulic cylinder (602) is fixedly connected to the supporting platform (101);

the lifting block (603), lifting block (603) sliding connection is on lifting support (601), lifting block (603) bottom fixed connection is on pneumatic cylinder (602).

3. The titanium alloy hot forging rapid production apparatus as recited in claim 1, wherein: the forging device (7) includes:

the forging power hammer (701) is fixedly connected to the two lifting blocks (603) through a bracket;

the flange hammer head (702), the flange hammer head (702) is fixedly connected to the bottom of the forging power hammer (701) through a flange.