CN112476801A - Cutting device with vibration separation function for floor cutting - Google Patents

Abstract

The invention provides a cutting device with a vibration separation function for cutting floors, relates to the technical field of floor processing, and solves the problems that floor breakage is easily caused when the force is not accurately controlled when a pressure arm is pressed, and the separation of the floors is realized by manually pressing the pressure arm after the cutting is finished, so that the operation is complicated; the problem that the residue cannot be cleaned synchronously while cutting through structural improvement is solved. The cutting device with the vibration separation function for cutting the floor comprises a main body seat; install cutting structure on the main part seat, and install limit structure on the main part seat. Because the head end of the air pipe is provided with the air collecting cover which is in a conical cover-shaped structure, and the tail end of the air pipe is positioned at the position 2cm behind the cutter, the collection of the wind power and the cleaning of the collected wind power to the residues at the cutting position can be automatically realized when the cutting structure moves forwards to realize the cutting by pushing the handle.

Description

Cutting device with vibration separation function for floor cutting

Technical Field

The invention belongs to the technical field of floor processing, and particularly relates to a cutting device with a vibration separation function for floor cutting.

Background

Modern people's anchor clamps are decorated and are generally used floor and pave ground, and the installation of floor is the last process of whole family decoration projects, the whole part of decoration projects has been accomplished before this, avoid secondary pollution, use floor decoration be, when spreading to places such as wall limit, need cut into the size that suits with it with the floor, at this moment need be used for the machine of floor cutting specially, the cutting of floor generally adopts the electric saw at present, but need the manual work to hold up the floor, can cause floor cutting department cutting inhomogeneous from this, not only waste floor raw materials, still brought certain economic loss for the user.

As in application No.: CN201310382633.9, the invention relates to a novel cutting machine for floors, which comprises a machine base, wherein a cutter is arranged on the machine base, the machine base is of a hollow structure, a cushion block for supporting a floor is arranged above the machine base, a limiting device for the floor is arranged in the machine base, a floor fixing device is also arranged on the machine base, the limiting device comprises a telescopic rod, one end of the telescopic rod is fixed in the machine base, a limiting plate for the floor is arranged at one end of the telescopic rod, a locking device is also arranged on the telescopic rod, the locking device comprises a C-shaped base for coating the telescopic rod, a locking screw is arranged at the upper end of the C-shaped base, and the C-shaped base is locked by. The invention has simple structure, convenient use, time and labor saving, greatly improves the efficiency of laying the floor, has low manufacturing cost and is convenient to carry.

Floor cutting devices similar to the above applications currently suffer from the following drawbacks:

one is that, when the existing device is used for cutting the floor, the pressing arm is often manually pressed to enable the cutter to be in contact with the floor, and then the cutting structure is pushed to perform cutting in a forward trial mode, so that the floor is easy to crack if the force can not be accurately controlled when the pressing arm is pressed, and the pressing arm is manually pressed to separate the floor after the cutting is finished, so that the operation is complicated; moreover, the existing device is easy to generate residues at the cutting position of the floor during cutting, the residues are easy to prick the hands of the operator, and the cleaning of the residues cannot be synchronously realized while cutting through structural improvement.

In view of the above, the present invention is to provide a cutting device with vibration separation function for cutting floor boards, which is improved based on the existing structure and defects, so as to achieve the purpose of more practical value.

Disclosure of Invention

In order to solve the technical problems, the invention provides a cutting device with a vibration separation function for cutting a floor, and aims to solve the problems that the existing device often needs to manually press a pressing arm to enable a cutter to be in contact with the floor when the floor is cut, then pushes a cutting structure to try cutting forward, the floor is easy to crack if the force is not accurately controlled when the pressing arm is pressed, and the floor is separated by manually pressing the pressing arm after the floor is cut, so that the operation is complicated; furthermore, the existing device is easy to generate residues at the cutting position of the floor during cutting, the residues are easy to prick the hands of the operator, and the problem that the residues can not be cleaned synchronously while cutting through structural improvement cannot be solved.

The invention is based on the purpose and the effect of a cutting device with a vibration separation function for floor cutting, and is achieved by the following specific technical means:

the cutting device with the vibration separation function for cutting the floor comprises a main body seat; the cutting structure is arranged on the main body seat, the limiting structure is arranged on the main body seat, and the auxiliary structure is arranged on the cutting structure; the main body seat comprises an auxiliary plate and a track hole, the auxiliary plate is welded on the top end face of the main body seat, and the auxiliary plate is provided with the track hole; the cutting structure comprises a handle, a cutter and an elastic piece A, and the cutter is arranged on the connecting seat; the elastic piece A is sleeved on the sliding seat A; the handle is in threaded connection with the connecting seat and penetrates through the track hole; the head end of the rail hole is of a bent structure, the elastic piece A is in a compressed state when the handle passes through a bent section of the rail hole, and the cutter is in a contact state with the floor; the auxiliary structure comprises a poke rod and a stress block, the poke rod is welded on the connecting plate, and the poke rod is of an L-shaped structure; the stress block is welded on the auxiliary plate, the bottom end face of the stress block is in contact with the poke rod when the cutting structure pushes 90cm forwards, and the bottom end face of the stress block is of an inclined structure.

Further, the main part seat includes the bracing piece, main part seat top end face welding has two spinal branch vaulting poles, and the bracing piece is the shaft-like structure of rectangle to two spinal branch vaulting poles have constituteed the support of floor jointly and have held up the structure.

Furthermore, the cutting structure comprises a sliding track, a sliding block, a sliding seat A and a connecting seat, the sliding track is welded on the top end face of the main body seat, and the sliding block is connected in the sliding track in a sliding manner; the top end face of the sliding block is fixedly connected with a sliding seat A through a bolt, and the sliding seat A is connected with a connecting seat in a limiting sliding mode.

Furthermore, the cutting structure also comprises an air pipe and a wind collecting cover, the air pipe is fixed on the connecting seat through a hoop, and the air pipe is of an L-shaped structure; the air pipe is characterized in that the head end of the air pipe is provided with an air collecting cover which is of a conical cover-shaped structure, and the tail end of the air pipe is positioned 2cm behind the cutter.

Furthermore, the limiting structure comprises two sliding rods A, a rectangular plate and a threaded rod, and the two sliding rods A are connected to the auxiliary plate in a sliding mode; the two sliding rods A penetrate through the sliding rails, and a rectangular plate is welded at the head ends of the two sliding rods A; the threaded rod is rotatably connected to the auxiliary plate and penetrates through the sliding rail; the threaded rod is in threaded connection with the rectangular plate, and the threaded rod and the sliding rod A jointly form a threaded adjusting structure of the rectangular plate.

Furthermore, the limiting structure also comprises a gear, a rotating seat and an adjusting rod, wherein the gear is welded on the threaded rod; the rotating seat is welded on the top end face of the main body seat, an adjusting rod is rotatably connected to the rotating seat, and spiral teeth are formed in the adjusting rod; the spiral teeth arranged on the adjusting rod are meshed with the gear, and the adjusting rod and the gear form a worm and gear structure together.

Furthermore, the auxiliary structure comprises a sliding seat B, sliding rods B, a connecting plate and an elastic piece B, wherein the sliding seat B is fixedly connected to the connecting seat through bolts, the sliding seat B is connected with the two sliding rods B in a sliding manner, and the two sliding rods B are welded with limit stop rings; the top of the two sliding rods B is welded with a connecting plate, the two sliding rods B are sleeved with elastic pieces B, and the two elastic pieces B jointly form an elastic reset structure of the sliding rods B.

Furthermore, the auxiliary structure further comprises a protrusion, the bottom end of the stress block is welded with the protrusion in a rectangular array shape, the protrusion is of a semi-cylindrical structure, and the protrusion welded in the rectangular array shape forms a vibration structure of the sliding rod B.

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

through the cooperation setting of accessory plate, cutting structure and accessory structure, can realize the contact cutting of cutter and floor automatically when promoting cutting structure forward, and can collect gaseous the clearance that realizes the cutting residue automatically when continuing to promote the in-process forward to can realize extrusion and vibrations formula separation of floor automatically when promoting to the end position, specifically as follows: firstly, the head end of the rail hole is of a bent structure, the elastic piece A is in a compressed state when the handle passes through a bent section of the rail hole, and the cutter is in a contact state with the floor, so that the cutter can be automatically contacted with the floor in the process of pushing the handle to move back and forth, and the cutting convenience is improved; secondly, a wind collecting cover is arranged at the head end of the air pipe, the wind collecting cover is in a conical cover-shaped structure, and the tail end of the air pipe is positioned 2cm behind the cutter, so that when the cutting structure moves forwards to realize cutting by pushing the handle, the collection of wind power and the cleaning of residues at the cutting part by the collected wind power can be automatically realized; thirdly, as the stress block is welded on the auxiliary plate, and the bottom end surface of the stress block is in contact with the poke rod when the cutting structure pushes 90cm forwards, and the bottom end surface of the stress block is of an inclined structure, the head end of the rod B is in contact with the floor under the extrusion of the stress block, and the extrusion separation of the floor is further realized; fourthly, the bottom end surface of the stress block is welded with the bulges in a rectangular array shape, the bulges are in semi-cylindrical structures, and the bulges welded in the rectangular array shape form a vibration structure of the sliding rod B, so that vibration separation of the floor can be realized.

Through the arrangement of the limiting structure, firstly, the threaded rod is in threaded connection with the rectangular plate, and the threaded rod and the sliding rod A jointly form a threaded adjusting structure of the rectangular plate, so that the limiting position of the floor can be adjusted; and secondly, the spiral teeth arranged on the adjusting rod are meshed with the gear, and the adjusting rod and the gear jointly form a worm and gear structure, so that automatic locking after the threaded rod rotates can be realized, and the convenience of adjusting the threaded rod is improved.

Drawings

Fig. 1 is a schematic axial view of the present invention.

Fig. 2 is an enlarged schematic view of fig. 1 at a.

Fig. 3 is an enlarged schematic view of fig. 1 at B according to the present invention.

Fig. 4 is a schematic axial view of the present invention in another direction of fig. 1.

Fig. 5 is an enlarged view of the structure of fig. 4C according to the present invention.

Fig. 6 is an enlarged axial view of the cutting structure and the spacing structure of the present invention.

Fig. 7 is an enlarged schematic view of the auxiliary structure of the present invention.

Fig. 8 is a right structural diagram of the auxiliary plate and the force-bearing block of the invention.

In the drawings, the corresponding relationship between the component names and the reference numbers is as follows:

1. a main body seat; 101. a support bar; 102. an auxiliary plate; 103. a track hole; 2. cutting the structure; 201. a sliding track; 202. a slider; 203. a sliding seat A; 204. a connecting seat; 205. a handle; 206. a cutter; 207. an elastic member A; 208. an air tube; 209. a wind collecting cover; 3. a limiting structure; 301. a slide bar A; 302. a rectangular plate; 303. a threaded rod; 304. a gear; 305. a rotating seat; 306. an adjusting lever; 4. an auxiliary structure; 401. a sliding seat B; 402. a slide bar B; 403. a connecting plate; 404. an elastic member B; 405. a poke rod; 406. a stress block; 407. and (4) protruding.

Detailed Description

The embodiments of the present invention will be described in further detail with reference to the drawings and examples. The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are only for convenience in describing and simplifying the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, 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 is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example (b):

as shown in figures 1 to 8:

the invention provides a cutting device with a vibration separation function for cutting a floor, which comprises a main body seat 1; the cutting structure 2 is arranged on the main body seat 1, the limiting structure 3 is arranged on the main body seat 1, and the auxiliary structure 4 is arranged on the cutting structure 2; referring to fig. 1, the main body base 1 includes an auxiliary plate 102 and a rail hole 103, the auxiliary plate 102 is welded on the top end surface of the main body base 1, and the auxiliary plate 102 is provided with a rail hole 103; the cutting structure 2 comprises a handle 205, a cutter 206 and an elastic piece A207, wherein the cutter 206 is arranged on the connecting seat 204; the elastic piece A207 is sleeved on the sliding seat A203; the handle 205 is screwed on the connecting seat 204, and the handle 205 passes through the track hole 103; the head end of the track hole 103 is of a curved structure, and when the handle 205 passes through a curved section of the track hole 103, the elastic part A207 is in a compressed state, and the cutter 206 is in a contact state with the floor, so that the contact between the cutter 206 and the floor can be automatically realized in the process of pushing the handle 205 to move back and forth, and the cutting convenience is further improved; referring to fig. 1, fig. 4 and fig. 5, the auxiliary structure 4 includes a tap rod 405 and a force-bearing block 406, the tap rod 405 is welded on the connecting plate 403, and the tap rod 405 is an L-shaped structure; the force receiving block 406 is welded on the auxiliary plate 102, and the bottom end surface of the force receiving block 406 is in contact with the poke rod 405 when the cutting structure 2 is pushed forward by 90cm, and the bottom end surface of the force receiving block 406 is in an inclined structure, so that the head end of the slide rod B402 is in contact with the floor under the extrusion of the force receiving block 406, and the extrusion separation of the floor is realized.

Referring to fig. 1, the main body base 1 includes two support rods 101, the two support rods 101 are welded on the top end surface of the main body base 1, the support rods 101 are rectangular rod-shaped structures, and the two support rods 101 jointly form a support supporting structure of the floor, so as to support the floor in a suspended state, thereby facilitating separation after subsequent cutting.

Referring to fig. 1 and 6, the cutting structure 2 includes a sliding rail 201, a sliding block 202, a sliding seat a203 and a connecting seat 204, the sliding rail 201 is welded on the top end surface of the main body seat 1, and the sliding block 202 is slidably connected in the sliding rail 201; the top end face of the sliding block 202 is fixedly connected with a sliding seat A203 through a bolt, and the sliding seat A203 is limited and slidably connected with a connecting seat 204.

Referring to fig. 1, the cutting structure 2 further includes an air tube 208 and a wind collecting cover 209, the air tube 208 is fixed on the connecting base 204 by a clamp, and the air tube 208 is an L-shaped structure; a wind-collecting cover 209 is installed at the head end of the air pipe 208, the wind-collecting cover 209 is a conical cover-shaped structure, and the tail end of the air pipe 208 is located 2cm behind the cutter 206, so that when the handle 205 is pushed to realize that the cutting structure 2 moves forwards to realize cutting, the collection of wind power and the cleaning of residues at the cutting position by the collected wind power can be automatically realized.

Referring to fig. 1 and 6, the limiting structure 3 comprises two sliding rods a301, a rectangular plate 302 and a threaded rod 303, wherein the two sliding rods a301 are slidably connected to the auxiliary plate 102; the two sliding rods A301 penetrate through the sliding rail 201, and a rectangular plate 302 is welded at the head ends of the two sliding rods A301; the threaded rod 303 is rotatably connected to the auxiliary plate 102, and the threaded rod 303 penetrates through the sliding rail 201; the threaded rod 303 is in threaded connection with the rectangular plate 302, and the threaded rod 303 and the sliding rod a301 jointly form a threaded adjusting structure of the rectangular plate 302, so that the floor limiting position can be adjusted.

Referring to fig. 1 and 3, the limiting structure 3 further includes a gear 304, a rotating seat 305 and an adjusting rod 306, wherein the gear 304 is welded on the threaded rod 303; the rotating seat 305 is welded on the top end face of the main body seat 1, the rotating seat 305 is rotatably connected with an adjusting rod 306, and the adjusting rod 306 is provided with spiral teeth; the spiral teeth arranged on the adjusting rod 306 are meshed with the gear 304, and the adjusting rod 306 and the gear 304 jointly form a worm and gear structure, so that automatic locking of the threaded rod 303 after rotation can be realized, and convenience in adjustment of the threaded rod 303 is improved.

Referring to fig. 7, the auxiliary structure 4 includes a sliding seat B401, a sliding rod B402, a connecting plate 403 and an elastic member B404, the sliding seat B401 is fixedly connected to the connecting seat 204 through bolts, the sliding seat B401 is slidably connected to the two sliding rods B402, and the two sliding rods B402 are welded with limit stop rings; the top of the two sliding rods B402 is welded with a connecting plate 403, the two sliding rods B402 are sleeved with an elastic piece B404, and the two elastic pieces B404 jointly form an elastic resetting structure of the sliding rods B402, so that the elastic resetting of the sliding rods B402 can be realized through the elastic pieces B404 after the shifting force of the connecting plate 403 disappears.

Referring to fig. 5, the auxiliary structure 4 further includes protrusions 407, the protrusions 407 are welded to the bottom end of the force-bearing block 406 in a rectangular array, the protrusions 407 are in a semi-cylindrical structure, and the protrusions 407 welded in a rectangular array form a vibration structure of the sliding rod B402, so that vibration separation of the floor can be achieved.

The specific use mode and function of the embodiment are as follows:

when the cutting device is used, the cutting structure 2 moves forwards when the handle 205 is pushed, firstly, the head end of the track hole 103 is of a bent structure, the elastic piece A207 is in a compressed state when the handle 205 passes through a bent section of the track hole 103, and the cutter 206 is in a contact state with the floor, so that the cutter 206 can be automatically contacted with the floor in the process of pushing the handle 205 to move forwards and backwards, and the cutting convenience is improved; secondly, as the head end of the air pipe 208 is provided with the air collecting cover 209, the air collecting cover 209 is in a conical cover-shaped structure, and the tail end of the air pipe 208 is positioned 2cm behind the cutter 206, the collection of wind power and the cleaning of residues at the cutting position by the collected wind power can be automatically realized when the cutting structure 2 moves forwards to realize cutting by pushing the handle 205; thirdly, as the force-bearing block 406 is welded on the auxiliary plate 102, and when the cutting structure 2 is pushed forward by 90cm, the bottom end surface of the force-bearing block 406 is in contact with the poke rod 405, and the bottom end surface of the force-bearing block 406 is in an inclined structure, the head end of the sliding rod B402 is in contact with the floor under the extrusion of the force-bearing block 406, and the extrusion separation of the floor is further realized; fourthly, since the bottom end surface of the stress block 406 is welded with the protrusions 407 in a rectangular array shape, the protrusions 407 are in a semi-cylindrical structure, and the protrusions 407 welded in a rectangular array shape form a vibration structure of the sliding rod B402, vibration separation of the floor can be realized.

The embodiments of the present 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 embodiment was 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 (8)

1. Cutting device who has vibrations separation function based on floor cutting usefulness, its characterized in that: comprises a main body seat (1); the cutting structure (2) is installed on the main body seat (1), the limiting structure (3) is installed on the main body seat (1), and the auxiliary structure (4) is installed on the cutting structure (2); the main body seat (1) comprises an auxiliary plate (102) and a track hole (103), the auxiliary plate (102) is welded on the top end face of the main body seat (1), and the track hole (103) is formed in the auxiliary plate (102); the cutting structure (2) comprises a handle (205), a cutter (206) and an elastic piece A (207), and the cutter (206) is installed on the connecting seat (204); the elastic piece A (207) is sleeved on the sliding seat A (203); the handle (205) is in threaded connection with the connecting seat (204), and the handle (205) penetrates through the track hole (103); the head end of the track hole (103) is of a bent structure, when the handle (205) passes through a bent section of the track hole (103), the elastic piece A (207) is in a compressed state, and the cutter (206) is in a contact state with the floor; the auxiliary structure (4) comprises a poke rod (405) and a stress block (406), the poke rod (405) is welded on the connecting plate (403), and the poke rod (405) is of an L-shaped structure; the force-bearing block (406) is welded on the auxiliary plate (102), and when the cutting structure (2) is pushed forward by 90cm, the bottom end face of the force-bearing block (406) is in contact with the poke rod (405), and the bottom end face of the force-bearing block (406) is of an inclined structure.

2. The cutting device with vibration separating function for cutting based on floor as claimed in claim 1, wherein: the floor support is characterized in that the main body seat (1) comprises support rods (101), two support rods (101) are welded on the top end face of the main body seat (1), the support rods (101) are of rectangular rod-shaped structures, and the support structure of the floor is formed by the two support rods (101) together.

3. The cutting device with vibration separating function for cutting based on floor as claimed in claim 1, wherein: the cutting structure (2) comprises a sliding track (201), a sliding block (202), a sliding seat A (203) and a connecting seat (204), the sliding track (201) is welded on the top end face of the main body seat (1), and the sliding block (202) is connected in the sliding track (201) in a sliding mode; the top end face of the sliding block (202) is fixedly connected with a sliding seat A (203) through a bolt, and the sliding seat A (203) is limited on the upper portion and is connected with a connecting seat (204) in a sliding mode.

4. The cutting device with vibration separating function for cutting based on floor as claimed in claim 1, wherein: the cutting structure (2) further comprises an air pipe (208) and a wind collecting cover (209), the air pipe (208) is fixed on the connecting seat (204) through a hoop, and the air pipe (208) is of an L-shaped structure; an air collecting cover (209) is installed at the head end of the air pipe (208), the air collecting cover (209) is of a conical cover-shaped structure, and the tail end of the air pipe (208) is located 2cm behind the cutter (206).

5. The cutting device with vibration separating function for cutting based on floor as claimed in claim 1, wherein: the limiting structure (3) comprises two sliding rods A (301), a rectangular plate (302) and a threaded rod (303), and the two sliding rods A (301) are connected to the auxiliary plate (102) in a sliding mode; the two sliding rods A (301) penetrate through the sliding rail (201), and a rectangular plate (302) is welded at the head ends of the two sliding rods A (301); the threaded rod (303) is rotatably connected to the auxiliary plate (102), and the threaded rod (303) penetrates through the sliding track (201); the threaded rod (303) is in threaded connection with the rectangular plate (302), and the threaded rod (303) and the sliding rod A (301) jointly form a threaded adjusting structure of the rectangular plate (302).

6. The cutting device with vibration separating function for cutting based on floor as claimed in claim 1, wherein: the limiting structure (3) further comprises a gear (304), a rotating seat (305) and an adjusting rod (306), and the gear (304) is welded on the threaded rod (303); the rotating seat (305) is welded on the top end face of the main body seat (1), the rotating seat (305) is rotatably connected with an adjusting rod (306), and the adjusting rod (306) is provided with spiral teeth; spiral teeth arranged on the adjusting rod (306) are meshed with the gear (304), and the adjusting rod (306) and the gear (304) jointly form a worm and gear structure.

7. The cutting device with vibration separating function for cutting based on floor as claimed in claim 1, wherein: the auxiliary structure (4) comprises a sliding seat B (401), sliding rods B (402), a connecting plate (403) and an elastic piece B (404), the sliding seat B (401) is fixedly connected to the connecting seat (204) through bolts, the sliding seat B (401) is connected with the two sliding rods B (402) in a sliding mode, and the two sliding rods B (402) are welded with limiting stop rings; the top of the two sliding rods B (402) is welded with a connecting plate (403), the two sliding rods B (402) are sleeved with an elastic piece B (404), and the two elastic pieces B (404) jointly form an elastic reset structure of the sliding rods B (402).

8. The cutting device with vibration separating function for cutting based on floor as claimed in claim 1, wherein: the auxiliary structure (4) further comprises a bulge (407), the bulge (407) is welded on the bottom end surface of the stress block (406) in a rectangular array mode, the bulge (407) is of a semi-cylindrical structure, and the bulge (407) welded in the rectangular array mode jointly forms a vibration structure of the sliding rod B (402).

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