CN212716706U - Novel hydraulic support transfers equipment - Google Patents

Abstract

The utility model discloses a novel hydraulic support transfers and moves equipment, include from moving the unit, transferring and move unit and guide unit, transfer and move the unit and set up on the unit from moving, guide unit sets up in the top from moving unit moving direction. The self-moving unit comprises a self-moving piece, a driving piece and a supporting piece, the adjusting and moving unit comprises a first telescopic piece and an adjusting and moving piece, and the guiding unit comprises a third support, a third telescopic piece and a fourth telescopic piece. The device of the utility model can ensure that the whole process of removing the hydraulic support is controlled remotely, thereby eliminating the hidden troubles that the winch is easy to break and hurts people and a pulley triangle area and the like in the previous frame removing process; the hydraulic support to be disassembled can be disassembled and adjusted in direction through the self-moving piece, the first telescopic piece and the adjusting piece.

Description

Novel hydraulic support transfers equipment

Technical Field

The utility model relates to a colliery is combined and is adopted technical field, especially a novel hydraulic support transfers and moves equipment.

Background

The stope face of the underground coal mine equipment comprehensive mechanized equipment is a fully mechanized face, and refers to the stope face with a hydraulic support, a high-power scraper conveyor and a double-drum shearer.

The speed of transportation, installation and removal of hydraulic supports, scraper machines and the like which are main equipment of modern fully mechanized mining production on the stope face of a coal mine is an important link for ensuring the continuation of mine production. In the underground coal mine, after the fully mechanized mining face is mined, hydraulic supports need to be removed and carried and are installed in a new fully mechanized mining face, the number of the supports of the fully mechanized mining face is large, the weight of the supports is large, each support is about dozens of to twenty tons, the weight of some supports reaches 40 tons, and the working strength of a transportation support is large; at present, a winch is used as a main tool for removing domestic hydraulic supports. There are two main methods of removal: firstly, pulling out the steel wire rope by using a winch, dragging the steel wire rope into a crossheading, and lifting and loading the steel wire rope; and secondly, pulling out the trolley by using a winch, dragging the trolley to a flat car on a working face loading platform, and carrying out. Installation, removal and transportation respectively take 15 days to a month, and have potential safety hazards.

The working procedures are various in the removing process, the structure and the efficiency of the removing equipment directly influence the removing speed of the working face, the production time of a mine is occupied, and the pressure is safely increased for the working face.

SUMMERY OF THE UTILITY MODEL

This section is for the purpose of summarizing some aspects of embodiments of the invention and to briefly introduce some preferred embodiments. Some simplifications or omissions may be made in this section and in the abstract of the specification and the title of the application to avoid obscuring the purpose of this section, the abstract of the specification and the title of the application, and such simplifications or omissions are not intended to limit the scope of the invention.

The utility model discloses a problem that exists among the equipment is transferred in view of above-mentioned and/or current hydraulic support has been proposed.

Therefore, the utility model aims to solve the problem of how to make and wait to tear open simple quick the removing of hydraulic support.

In order to solve the technical problem, the utility model provides a following technical scheme: the hydraulic support adjusting and moving equipment comprises a self-moving unit, a driving unit and a supporting unit, wherein the self-moving unit comprises a self-moving piece, a driving piece arranged on the self-moving piece and a supporting piece arranged on the side surface of the self-moving piece, and the self-moving piece can be integrated and split; and the number of the first and second groups,

transfer move the unit, set up in on the piece moves from, including swivelling joint move the piece with transferring from the first extensible member on the piece, the flexible end of extensible member with it is articulated to transfer.

As a novel hydraulic support transfers an optimal scheme of moving equipment, wherein: when the self-moving piece is split, the self-moving piece comprises a first self-moving piece and a second self-moving piece arranged side by side with the first self-moving piece; the driving piece is a hydraulic jack and is connected with the first self-moving piece and the second self-moving piece; the supporting piece comprises a first supporting piece arranged on the side surface of the first self-moving piece and a second supporting piece arranged on the side surface of the second self-moving piece.

As a novel hydraulic support transfers an optimal scheme of moving equipment, wherein: the bottom end of the first supporting part is hinged with the bottom of the first self-moving part, and the side surface of the first supporting part is hinged with the top of the first self-moving part through a first connecting part.

As a novel hydraulic support transfers an optimal scheme of moving equipment, wherein: the bottom end of the second supporting piece is hinged with the bottom of the second self-moving piece, and the side surface of the second supporting piece is hinged with the top of the second self-moving piece through a second connecting piece.

As a novel hydraulic support transfers an optimal scheme of moving equipment, wherein: the first telescopic piece and the adjusting and moving piece are connected to the second self-moving piece in a rotating mode, and the first telescopic piece is arranged between the adjusting and moving piece and the first self-moving piece.

As a novel hydraulic support transfers an optimal scheme of moving equipment, wherein: when the self-moving piece is integral, the driving piece comprises a motor arranged in the self-moving piece and a crawler arranged on the side surface of the self-moving piece.

As a novel hydraulic support transfers an optimal scheme of moving equipment, wherein: the bottom end of the supporting piece is hinged with the bottom of the self-moving piece, and the side surface of the supporting piece is hinged with the top of the self-moving piece through a third connecting piece.

As a novel hydraulic support transfers an optimal scheme of moving equipment, wherein: the self-moving piece is fixedly provided with a first supporting seat in rotary connection with the first telescopic piece and a second supporting seat in rotary connection with the adjusting and moving piece.

As a novel hydraulic support transfers an optimal scheme of moving equipment, wherein: the adjusting and moving piece comprises a second telescopic piece arranged in the adjusting and moving piece and a hanging rack connected with the telescopic end of the second telescopic piece.

As a novel hydraulic support transfers an optimal scheme of moving equipment, wherein: still include the guide unit, set up in from the top of moving a moving direction, include with from moving a third support of fixed connection, and respectively with third support articulated third extensible member and fourth extensible member.

The hydraulic support frame has the advantages that the hydraulic support frame can be remotely controlled in the whole removing process, and the hidden dangers that a winch is easy to break and hurts people, a pulley triangular area and the like in the previous frame removing process are eliminated; the hydraulic support to be disassembled can be disassembled and adjusted in direction through the self-moving piece, the first telescopic piece and the adjusting piece.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required to be used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to these drawings without inventive labor. Wherein:

fig. 1 is the utility model discloses a novel hydraulic support transfers scene graph of moving equipment.

Fig. 2 is the structure diagram of the novel hydraulic support transfer device.

Fig. 3 is a top view of the novel hydraulic support adjusting and moving device.

Fig. 4 is the structure diagram of the novel hydraulic support adjusting and moving device when the self-moving piece is integral.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention more comprehensible, embodiments accompanying the present invention are described in detail below with reference to the accompanying drawings.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, but the present invention may be implemented in other ways different from the specific details set forth herein, and one skilled in the art may similarly generalize the present invention without departing from the spirit of the present invention, and therefore the present invention is not limited to the specific embodiments disclosed below.

Furthermore, the references herein to "one embodiment" or "an embodiment" refer to a particular feature, structure, or characteristic that may be included in at least one implementation of the invention. The appearances of the phrase "in one embodiment" in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments.

In coal mine production, after the fully mechanized coal face (stope face) is finished, along with the forward progress of coal mining work, the hydraulic supports and other equipment arranged on the fully mechanized coal face need to be withdrawn in sequence. The traditional hydraulic support is basically dismantled by matching a winch with a return pulley, the support is pulled out from a working face stop position, a single body needs to be lifted manually in the pulling-out process to assist in adjusting the direction, and the support is pulled away and conveyed out by the winch after being pulled out. The construction method is low in speed, high in potential safety hazard, high in labor intensity, large in labor amount and complex in working links, 7-8 workers are generally used for dismantling one frame, and the average time is about one hour. During the dismantling process, accidents such as people injury caused by broken steel wire ropes, people injury caused by back-end pulleys, single body collapse and bullet are frequent, the steel wire ropes are frequently clamped into and taken out of the pulleys, the single body repeatedly pushes different parts of the support, the winch is remotely and frequently started and stopped, and management cadres with abundant experience for many years are required to carry out field command. When the large-scale support is dismantled, in order to safely utilize a support bottom lifting jack to repeatedly lift and fall the support to realize forward movement or a fulcrum is arranged in front of the support to realize forward movement through a chain and a push sliding cylinder, but the speed is slower.

Example 1

The utility model discloses a first embodiment, this embodiment provide a novel hydraulic support transfers and moves equipment, novel hydraulic support transfers and moves equipment and include from moving unit 100 and transferring and move unit 200, transfers and moves unit 200 and set up on the piece 101 that moves from moving, realizes the removal of whole equipment from moving unit 100, transfers and moves unit 200 and will wait to tear open hydraulic support and tear open and transfer to.

For the explanation of subsequent structure, the utility model discloses three orthogonal direction has in the three-dimensional space that the hydraulic support of definition transfers equipment place, is vertical, horizontal and vertical respectively. Wherein, the horizontal direction of the forward and backward travel of the self-moving piece 101 is horizontal; the other horizontal direction vertical to the longitudinal direction is a transverse direction; the vertical direction is vertical.

Specifically, the self-moving unit 100 comprises a self-moving member 101, a driving member 102 disposed on the self-moving member 101, and a supporting member 103 disposed on a side surface of the self-moving member 101, and the self-moving member 101 may be an integral type or a split type. The adjusting and moving unit 200 comprises a first telescopic member 201 and an adjusting and moving member 202 which are rotatably connected to the self-moving member 101, and the telescopic end of the telescopic member 201 is hinged with the adjusting and moving member 202.

When the self-moving part 101 is a split type, the self-moving part 101 comprises a first self-moving part 101a and a second self-moving part 101b arranged side by side with the first self-moving part 101 a; the driving member 102 is a hydraulic jack, which is fixedly connected to the first self-moving member 101a, and the telescopic end is connected to the second self-moving member 101b, when the position of the first self-moving member 101a is fixed, the driving member 102 can move the second self-moving member 101b forward, and when the position of the second self-moving member 101b is fixed, the driving member 102 can pull the first self-moving member 101a to move. The supporting member 103 includes a first supporting member 103a disposed on a side of the first self-moving member 101a, and a second supporting member 103b disposed on a side of the second self-moving member 101 b. The bottom end of the first supporting part 103a is hinged with the bottom of the first self-moving part 101a, the side surface thereof is hinged with the top of the first self-moving part 101a through a first connecting part 103a-1, the bottom end of the second supporting part 103b is hinged with the bottom of the second self-moving part 101b, and the side surface thereof is hinged with the top of the second self-moving part 101b through a second connecting part 103 b-1. Preferably, the first supporting member 103a and the second supporting member 103b are both telescopic hydraulic cylinders, and the telescopic ends of the first supporting member 103a and the second supporting member 103b support the top of the mine hole or a hydraulic support to be disassembled to fix the first self-moving member 101a or the second self-moving member 101 b. Preferably, the first connecting member 103a-1 and the second connecting member 103b-1 are also telescopic hydraulic cylinders, the bottom end of the first connecting member 103a-1 is hinged to the top surface of the first self-moving member 101a, and the telescopic end thereof is hinged to the side surface of the first supporting member 103a, i.e. the first connecting member 103a-1 can control the first supporting member 103a to rotate, which is set because when the telescopic end of the first supporting member 103a extends upwards, if the first connecting member encounters dangerous or insufficient-strength objects such as cables, etc., the first supporting member 103a can rotate by a certain angle to avoid the objects to support. The second support 103b is similar to the first support 103a, and will not be described in detail herein. The first telescopic part 201 and the adjusting and moving part 202 are both connected to the second self-moving part 101b in a rotating mode, the first telescopic part 201 is arranged between the adjusting and moving part 202 and the first self-moving part 101a, namely the forward direction of the self-moving part 101 is defined as the front direction, the first telescopic part 201 is arranged in front of the adjusting and moving part 202, and the reason for the arrangement is that the first telescopic part 201 can pull the adjusting and moving part 202 to turn in a larger angle. The self-moving part 101 is fixedly provided with a first supporting seat 101c which is rotatably connected with the first telescopic part 201 and a second supporting seat 101d which is rotatably connected with the moving adjusting part 202, the moving adjusting part 202 comprises a second telescopic part 202a arranged in the moving adjusting part and a hanging rack 202b connected with the telescopic end of the second telescopic part 202a, and the hydraulic support to be disassembled is connected with the hanging rack 202 b. Preferably, the first telescopic member 201 and the second telescopic member 202a are both telescopic hydraulic cylinders. When the hydraulic support is used, the first supporting piece 103a and the second supporting piece 103b are supported on the hydraulic support to be disassembled, the whole equipment is arranged below a top plate of the hydraulic support to be disassembled, the hydraulic support to be disassembled beside the hanger 202b is connected onto the hanger 202b, the hydraulic support is longitudinally pulled out through the second telescopic piece 202a, then the first telescopic piece 201 is contracted, the hydraulic support is turned, and the process can be carried out simultaneously. And then the connection between the hanger 202b and the hydraulic bracket is released, the first supporting piece 103a is lowered, the driving piece 102 is controlled to push the first self-moving piece 101a to move forwards, when the hydraulic bracket moves to the next hydraulic bracket to be dismounted, the first supporting piece 103a is lifted to be abutted against the top plate or the cross beam of the hydraulic bracket, so that the first self-moving piece 101a is fixed, then the second supporting piece 103b is lowered, the driving piece 102 is controlled to contract, the second self-moving piece 101b is pulled to move forwards, after the hydraulic bracket moves to a specified position, the second supporting piece 103b is lifted to be abutted against the top plate or the cross beam of the hydraulic bracket, so that the second self-moving piece 101b is fixed, and the next hydraulic bracket to be dismounted is connected. The above-mentioned cyclic action is used for making periodic reciprocating movement, so that the hydraulic supports to be removed can be removed one by one and their direction can be regulated.

When the self-moving member 101 is an integral type, as shown in fig. 4, the driving member 102 includes a motor 102a disposed inside the self-moving member 101, and a crawler belt 102b disposed on a side surface of the self-moving member 101, and the bottom end of the supporting member 103 is hinged to the bottom of the self-moving member 101, and a side surface thereof is hinged to the top of the self-moving member 101 through a third connecting member 103 c. The motor 102a drives the track 102b to move forward through gear transmission or other transmission modes. The first telescopic member 201 and the moving adjusting member 202 are both disposed on the self-moving member 101, and the rest of the structure is the same as that of the self-moving member 101 in a split type, so that the description thereof will not be made herein. When the device is used, the moving mode is that the supporting piece 103 is dropped when the device needs to be moved, the control motor 102a rotates to drive the crawler belt 102b to move forwards, when the device does not need to be moved, the supporting piece 103 is jacked up, and the rest operations are the same when the device 101 is in a split type, so that the description is not repeated.

Example 2

The second embodiment of the present invention, which is different from the first embodiment, is: a guide unit 300 is also included. In the last embodiment, the novel hydraulic support adjusting and moving device comprises a self-moving unit 100 and an adjusting and moving unit 200, wherein the adjusting and moving unit 200 is arranged on a self-moving part 101, the self-moving unit 100 realizes the movement of the whole device, and the adjusting and moving unit 200 detaches and adjusts the direction of the hydraulic support to be detached.

Specifically, the self-moving unit 100 comprises a self-moving member 101, a driving member 102 disposed on the self-moving member 101, and a supporting member 103 disposed on a side surface of the self-moving member 101, and the self-moving member 101 may be an integral type or a split type. The adjusting and moving unit 200 comprises a first telescopic member 201 and an adjusting and moving member 202 which are rotatably connected to the self-moving member 101, and the telescopic end of the telescopic member 201 is hinged with the adjusting and moving member 202.

When the self-moving part 101 is a split type, as shown in fig. 1 to 3, in fig. 1, a represents a hydraulic support adjusting and moving device, B represents a hydraulic support to be disassembled, C represents a hydraulic support being disassembled, and D represents a shield support. The self-moving part 101 comprises a first self-moving part 101a and a second self-moving part 101b arranged side by side with the first self-moving part 101 a; the driving member 102 is a hydraulic jack, which is fixedly connected to the first self-moving member 101a, and the telescopic end is connected to the second self-moving member 101b, when the position of the first self-moving member 101a is fixed, the driving member 102 can move the second self-moving member 101b forward, and when the position of the second self-moving member 101b is fixed, the driving member 102 can pull the first self-moving member 101a to move. The supporting member 103 includes a first supporting member 103a disposed on a side of the first self-moving member 101a, and a second supporting member 103b disposed on a side of the second self-moving member 101 b. The bottom end of the first supporting part 103a is hinged with the bottom of the first self-moving part 101a, the side surface thereof is hinged with the top of the first self-moving part 101a through a first connecting part 103a-1, the bottom end of the second supporting part 103b is hinged with the bottom of the second self-moving part 101b, and the side surface thereof is hinged with the top of the second self-moving part 101b through a second connecting part 103 b-1. Preferably, the first supporting member 103a and the second supporting member 103b are both telescopic hydraulic cylinders, and the telescopic ends of the first supporting member 103a and the second supporting member 103b support the top of the mine hole or a hydraulic support to be disassembled to fix the first self-moving member 101a or the second self-moving member 101 b. Preferably, the first connecting member 103a-1 and the second connecting member 103b-1 are also telescopic hydraulic cylinders, the bottom end of the first connecting member 103a-1 is hinged to the top surface of the first self-moving member 101a, and the telescopic end thereof is hinged to the side surface of the first supporting member 103a, i.e. the first connecting member 103a-1 can control the first supporting member 103a to rotate, which is set because when the telescopic end of the first supporting member 103a extends upwards, if the first connecting member encounters dangerous or insufficient-strength objects such as cables, etc., the first supporting member 103a can rotate by a certain angle to avoid the objects to support. The second support 103b is similar to the first support 103a, and will not be described in detail herein. The first telescopic part 201 and the adjusting and moving part 202 are both connected to the second self-moving part 101b in a rotating mode, the first telescopic part 201 is arranged between the adjusting and moving part 202 and the first self-moving part 101a, namely the forward direction of the self-moving part 101 is defined as the front direction, the first telescopic part 201 is arranged in front of the adjusting and moving part 202, and the reason for the arrangement is that the first telescopic part 201 can pull the adjusting and moving part 202 to turn in a larger angle. The self-moving part 101 is fixedly provided with a first supporting seat 101c which is rotatably connected with the first telescopic part 201 and a second supporting seat 101d which is rotatably connected with the moving adjusting part 202, the moving adjusting part 202 comprises a second telescopic part 202a arranged in the moving adjusting part and a hanging rack 202b connected with the telescopic end of the second telescopic part 202a, and the hydraulic support to be disassembled is connected with the hanging rack 202 b. Preferably, the first telescopic member 201 and the second telescopic member 202a are both telescopic hydraulic cylinders. When the hydraulic support is used, the first supporting piece 103a and the second supporting piece 103b are supported on the hydraulic support to be disassembled, the whole equipment is arranged below a top plate of the hydraulic support to be disassembled, the hydraulic support to be disassembled beside the hanger 202b is connected onto the hanger 202b, the hydraulic support is longitudinally pulled out through the second telescopic piece 202a, then the first telescopic piece 201 is contracted, the hydraulic support is turned, and the process can be carried out simultaneously. And then the connection between the hanger 202b and the hydraulic bracket is released, the first supporting piece 103a is lowered, the driving piece 102 is controlled to push the first self-moving piece 101a to move forwards, when the hydraulic bracket moves to the next hydraulic bracket to be dismounted, the first supporting piece 103a is lifted to be abutted against the top plate or the cross beam of the hydraulic bracket, so that the first self-moving piece 101a is fixed, then the second supporting piece 103b is lowered, the driving piece 102 is controlled to contract, the second self-moving piece 101b is pulled to move forwards, after the hydraulic bracket moves to a specified position, the second supporting piece 103b is lifted to be abutted against the top plate or the cross beam of the hydraulic bracket, so that the second self-moving piece 101b is fixed, and the next hydraulic bracket to be dismounted is connected. The above-mentioned cyclic action is used for making periodic reciprocating movement, so that the hydraulic supports to be removed can be removed one by one and their direction can be regulated. The guiding unit 300 is arranged at the top end of the moving direction of the self-moving part 101, and comprises a third support 301 fixedly connected with the self-moving part 101, and a third telescopic part 302 and a fourth telescopic part 303 respectively hinged with the third support 301, preferably, the third telescopic part 302 and the fourth telescopic part 303 are telescopic hydraulic cylinders, the guiding unit 300 is arranged in order to enable the traveling route of the whole equipment to be carried out according to a specified route, and to deviate from the route when the equipment travels, and the traveling route of the equipment can be returned by enabling the telescopic ends of the third telescopic part 302 and the fourth telescopic part 303 to abut against a base of a hydraulic support to be dismounted or an object.

When the self-moving part 101 is a single body, the driving part 102 includes a motor 102a disposed inside the self-moving part 101, and a caterpillar 102b disposed on a side surface of the self-moving part 101, and the bottom end of the supporting part 103 is hinged to the bottom of the self-moving part 101, and the side surface thereof is hinged to the top of the self-moving part 101 through a third connecting part 103 c. The motor 102a drives the track 102b to move forward through gear transmission or other transmission modes. The first telescopic member 201 and the moving adjusting member 202 are both disposed on the self-moving member 101, and the rest of the structure is the same as that of the self-moving member 101 in a split type, so that the description thereof will not be made herein. When the device is used, the moving mode is that the supporting piece 103 is dropped when the device needs to be moved, the control motor 102a rotates to drive the crawler belt 102b to move forwards, when the device does not need to be moved, the supporting piece 103 is jacked up, and the rest operations are the same when the device 101 is in a split type, so that the description is not repeated.

It should be noted that the above embodiments are only used for illustrating the technical solutions of the present invention and not for limiting, and although the present invention has been described in detail with reference to the preferred embodiments, those skilled in the art should understand that the technical solutions of the present invention can be modified or replaced with equivalents without departing from the spirit and scope of the technical solutions of the present invention, which should be covered by the scope of the claims of the present invention.

Claims (10)

1. The utility model provides a novel hydraulic support transfers equipment which characterized in that: comprises the steps of (a) preparing a mixture of a plurality of raw materials,

the self-moving unit (100) comprises a self-moving piece (101), a driving piece (102) arranged on the self-moving piece (101), and a supporting piece (103) arranged on the side surface of the self-moving piece (101), wherein the self-moving piece (101) can be integrated and split; and the number of the first and second groups,

the adjusting and moving unit (200) is arranged on the self-moving part (101) and comprises a first telescopic part (201) and an adjusting and moving part (202) which are connected to the self-moving part (101) in a rotating mode, and the telescopic end of the telescopic part (201) is hinged to the adjusting and moving part (202).

2. The novel hydraulic support transfer apparatus of claim 1, wherein: when the self-moving piece (101) is split, the self-moving piece (101) comprises a first self-moving piece (101a) and a second self-moving piece (101b) arranged side by side with the first self-moving piece (101 a); the driving part (102) is a hydraulic jack which is connected with the first self-moving part (101a) and the second self-moving part (101 b);

the supporting piece (103) comprises a first supporting piece (103a) arranged on the side surface of the first self-moving piece (101a) and a second supporting piece (103b) arranged on the side surface of the second self-moving piece (101 b).

3. The novel hydraulic support transfer apparatus of claim 2, wherein: the bottom end of the first supporting piece (103a) is hinged with the bottom of the first self-moving piece (101a), and the side surface of the first supporting piece is hinged with the top of the first self-moving piece (101a) through a first connecting piece (103 a-1).

4. A novel hydraulic prop displacement device, as claimed in claim 2 or 3, characterized in that: the bottom end of the second supporting part (103b) is hinged with the bottom of the second self-moving part (101b), and the side surface of the second supporting part is hinged with the top of the second self-moving part (101b) through a second connecting part (103 b-1).

5. The novel hydraulic support transfer apparatus of claim 4, wherein: the first telescopic piece (201) and the adjusting and moving piece (202) are connected to the second self-moving piece (101b) in a rotating mode, and the first telescopic piece (201) is arranged between the adjusting and moving piece (202) and the first self-moving piece (101 a).

6. The novel hydraulic support transfer apparatus of claim 1, wherein: when the self-moving piece (101) is integral, the driving piece (102) comprises a motor (102a) arranged inside the self-moving piece (101) and a crawler belt (102b) arranged on the side surface of the self-moving piece (101).

7. The novel hydraulic support transfer apparatus of claim 6, wherein: the bottom end of the supporting part (103) is hinged with the bottom of the self-moving part (101), and the side surface of the supporting part is hinged with the top of the self-moving part (101) through a third connecting part (103 c).

8. The new hydraulic support transfer apparatus of claim 5 or 7, wherein: and a first supporting seat (101c) rotationally connected with the first telescopic piece (201) and a second supporting seat (101d) rotationally connected with the adjusting piece (202) are fixedly arranged on the self-moving piece (101).

9. The novel hydraulic support transfer apparatus of claim 8, wherein: the adjusting and moving piece (202) comprises a second telescopic piece (202a) arranged in the adjusting and moving piece and a hanging rack (202b) connected with the telescopic end of the second telescopic piece (202 a).

10. The novel hydraulic support transfer apparatus of claim 9, wherein: the device also comprises a guide unit (300) which is arranged at the top end of the moving direction of the self-moving piece (101), and comprises a third support (301) fixedly connected with the self-moving piece (101), and a third telescopic piece (302) and a fourth telescopic piece (303) which are respectively hinged with the third support (301).

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