CN220870470U - Infrared ray glance flat instrument regulating frame - Google Patents

Abstract

The utility model discloses an infrared ray leveling instrument adjusting frame, which belongs to the technical field of adjusting frames and comprises a frame body, wherein the upper end of the frame body is connected with a sliding groove in a sliding manner, and the lower part of the frame body is connected with a rotating device. The bottom of the frame body is fixedly connected with the fixed shaft, the bottom of the frame body is rotationally connected with the rotating cylinder, and the inside of the fixed shaft is hollow. The rotating cylinder is coated on the outer side of the fixed shaft, the groove is positioned on the inner side of the rotating cylinder, and the brake sheets are positioned on two sides of the fixed shaft. The first spring is positioned between the brake sheet and the fixed shaft, and the pull rope penetrates through the fixed shaft to be connected with the brake sheet. The rotating cylinder is rotationally connected with a first telescopic rod, the other end of the first telescopic rod is connected with a second telescopic rod in a ball mode, and the second telescopic rod is connected with an infrared ray leveling instrument. The problems of low moving efficiency and overlarge shaking amplitude when the wall body is regularly scanned by the movable infrared scanning instrument are solved.

Description

Infrared ray glance flat instrument regulating frame

Technical Field

The utility model belongs to the technical field of adjusting frames, and particularly relates to an infrared ray leveling instrument adjusting frame.

Background

The construction of the masonry engineering accurate positioning is characterized in that the construction of the erection by adopting an infrared ray leveling instrument replaces the traditional guy construction, thereby ensuring the accuracy of the wall body position and improving the verticality and the flatness qualification rate of the wall body. Traditional guy wires are limited to a great extent by the technical flatness of workers, and problems are more caused after construction is completed, and the straightness and flatness qualification rate are poor. The prior patent CN 104060839B is specially used for the construction control method of the vertical keel of the steel structure of the metal curtain wall of the large-scale venue, and the design elevation of the infrared laser leveling instrument is locked to be 0.5m above the elevation of the floor slab; however, the existing infrared ray leveling instrument is usually manually moved to level the wall body, but the manual movement efficiency is low and the shaking amplitude is too large, so that an adjusting frame of the infrared ray leveling instrument is needed to improve the working efficiency and reduce the shaking amplitude.

Disclosure of utility model

Therefore, the utility model aims to provide an infrared ray leveling instrument adjusting frame, which aims to solve the problems of low moving efficiency and overlarge shaking amplitude when a wall body is regularly leveled by a moving infrared ray leveling instrument.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

The utility model relates to an infrared ray leveling instrument adjusting frame, which comprises a frame body, wherein the upper end of the frame body is connected with a sliding groove in a sliding manner, the sliding groove is formed by splicing a plurality of blocks, the lower part of the frame body is connected with a rotating device, and the rotating device comprises: the novel infrared scanning type air conditioner comprises a rotating cylinder, braking sheets, a fixed shaft, a first spring, a groove and a pull rope, wherein the bottom of the frame body is fixedly connected with the fixed shaft, the inside of the fixed shaft is hollow, the bottom of the frame body is rotationally connected with the rotating cylinder, the rotating cylinder is coated on the outer side of the fixed shaft, the groove is positioned on the inner side of the rotating cylinder, the braking sheets are positioned on two sides of the fixed shaft, the first spring is positioned between the braking sheets and the fixed shaft, the pull rope penetrates through the fixed shaft to be connected with the braking sheets, the rotating cylinder is rotationally connected with a first telescopic rod, the other end of the first telescopic rod is in ball joint with a second telescopic rod, a fixed block is penetrated by the pull rope, a plurality of blocks are respectively connected with the first telescopic rod and the second telescopic rod, the other end of the pull rope penetrates through the first telescopic rod and the fixed block, and the second telescopic rod is connected with an infrared scanning instrument.

Further, the second telescopic link includes interior pole and outer pole, interior pole be located outer pole inside and with outer pole sliding connection, the second telescopic link is connected with the regulation portion of adjusting second telescopic link length, the regulation portion includes: the rotary shaft is rotationally connected with the outer rod, the middle part of the baffle is fixedly connected with the rotary shaft, the second spring is positioned between the outer rod and the baffle, and the other end of the pull rope is connected with the lower end of the baffle.

Further, the baffle is the slant setting, baffle upper end and interior pole contact, baffle upper end bottom is the rubber material.

Further, the pull rope is provided for the segment and is rotatably connected.

Further, the upper end of the frame body is rotationally connected with a roller, and the roller is in rolling connection with the chute.

The utility model has the beneficial effects that:

According to the infrared scanner adjusting frame, the spliced sliding grooves are used for adapting to different environment requirements, so that the frame body can drive the infrared scanner to scan a plane; the first telescopic rod is rotated to drive the infrared leveling instrument to regularly level different directions; the infrared ray leveling instrument can be adjusted in vertical height through the second telescopic rod and the adjusting part, and the requirements of different heights are met. The rotation angle of the rotating device and the vertical height of the adjusting part to the second telescopic rod can be controlled through the pull rope, so that the operation is more convenient.

Additional advantages, objects, and features of the utility model will be set forth in part in the description which follows and in part will become apparent to those having ordinary skill in the art upon examination of the following or may be learned from practice of the utility model. The objects and other advantages of the utility model may be realized and obtained by means of the instrumentalities and combinations particularly pointed out in the specification.

Drawings

In order to make the objects, technical solutions and advantageous effects of the present utility model more clear, the present utility model provides the following drawings for description:

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is a cross-sectional view of a rotating drum of the present utility model;

FIG. 3 is a side view of the present utility model;

FIG. 4 is an enlarged schematic view of the present utility model at B.

The figures are marked as follows: 1. a frame body; 2. a chute; 3. a first telescopic rod; 4. a rotating device; 41. a rotating cylinder; 42. a fixed shaft; 43. a first spring; 44 grooves; 45. a pull rope; 46. a fixed block; 47. a brake piece; 5. a second telescopic rod; 51. an outer rod; 52. an inner rod; 6. an infrared ray leveling instrument; 7. an adjusting section; 71. a baffle; 72. a rotating shaft; 73. a second spring; 8. and a roller.

Detailed Description

As shown in fig. 1 to 4, the adjusting frame of the infrared ray flatness-adjusting instrument comprises a frame body 1, wherein rollers 8 are rotatably connected to the upper end of the frame body 1, the number of the rollers 8 is two, the rollers 8 are oppositely arranged at two ends of the frame body 1, and the rollers 8 can reduce vibration generated when the frame body 1 slides. The upper end of the frame body 1 is connected with a chute 2 in a sliding way, and the roller is connected with the chute 2 in a rolling way. The chute 2 is formed by splicing a plurality of blocks, so that the length of the chute 2 can be increased to adapt to different scenes. The chute 2 can be mounted in the room by means of bolts or the like. The lower part of the frame body 1 is connected with a rotating device 4, and the rotating device 4 comprises: the rotary drum 41, the brake piece 47, the fixed shaft 42, the first spring 43, the groove 44 and the pull cord 45. The bottom of the frame body 1 is fixedly connected with the fixed shaft 42, and the bottom of the frame body 1 is rotatably connected with the rotary cylinder 41. The diameter of the rotating cylinder 41 is larger than that of the fixed shaft 42, and the rotating cylinder 41 is coated on the outer side of the fixed shaft 42. The rotary cylinder 41 has a length longer than that of the fixed shaft 42, and the fixed shaft 42 is hollow. The brake disc 47 is located at two sides of the fixed shaft 42, the first spring 43 is located between the brake disc 47 and the fixed shaft 42, and the brake disc 47 is propped open under the normal state of the first spring 43, so that the brake disc 47 is in contact with the rotating cylinder 41. The pull rope 45 passes through the fixed shaft 42 and is connected with the brake piece 47, the pull rope 45 is obliquely connected with the brake piece 47, the pull rope 45 is convenient to pull downwards, and the pull rope 45 is pulled to prevent the brake piece 47 from contacting the rotary drum 41. The rotating cylinder 41 is rotatably connected with a first telescopic rod 3, and the first telescopic rod 3 is used for transversely stretching. The other end of the first telescopic rod 3 is connected with a second telescopic rod 5 in a ball mode, and the second telescopic rod 5 is used for vertically lifting. The fixing block 46 is provided with a plurality of fixing blocks which are respectively connected with the first telescopic rod 3 and the second telescopic rod 5, so that the pull rope 45 can fix the orientation without shaking everywhere. The pull rope 45 is provided with a section and is rotatably connected, and the section point of the pull rope 45 is arranged inside the fixed shaft 42, so that the pull rope 45 cannot be twisted when the first telescopic rod 3 rotates. The other end of the pull rope 45 penetrates through the first telescopic rod 3 and the fixed block 46, and the second telescopic rod 5 is connected with the infrared ray flatness scanner 6.

The length of the further pulling rope 461 is the sum of the first telescopic rod 3 and the second telescopic rod 5. The other end of the first telescopic rod 3 is connected with a second telescopic rod 5 in a ball joint mode. The second telescopic rod 5 comprises an inner rod 52 and an outer rod 51, the inner rod 52 being located inside the outer rod 51 and being slidingly connected to the outer rod 51. The second telescopic rod 5 is connected with an adjusting part 7 for adjusting the length of the second telescopic rod 5. The adjusting section 7 includes: a rotation shaft 72, a second spring 73 and a shutter 71. The rotating shaft 72 is rotatably connected with the outer rod 51, and the middle part of the baffle 71 is fixedly connected with the rotating shaft 72. The second spring 73 is located between the outer rod 51 and the baffle 71. The baffle 71 is the slant setting, and baffle 71 upper end and interior pole 52 contact, and baffle 71 upper end is vertical setting and more laminating interior pole 52, baffle 71 upper end bottom is the rubber material. The other end of the pull rope 45 is connected with the lower end of the baffle 71. Pulling the pull cord 45 rotates the flap 71.

The working process of the scheme comprises the following steps: when the wall body needs to be subjected to the leveling treatment, the chute 2 is fixed on a ceiling or a beam bottom through parts such as bolts and the like by the chute 2. And then the infrared ray leveler 6 is aligned to the wall side line by pulling the frame body 1. The first telescopic rod 3 is normally horizontal to level the wall parallel to the chute 2 by placing the infrared level 6 on the ground to align the basement when the wall is to be built. The length of the second telescopic rod 5 is adjusted at this time. By pulling the pull cord 45 to rotate the shutter 71, the second spring 73 is forced to compress, and the upper end of the shutter 71 no longer abuts against the inner rod 52. The inner rod 52 is allowed to slide with the outer rod 51 at this time to adjust the vertical distance of the infrared ray swinger 6. When the height of the infrared ray scanner 6 is determined, the pull rope 45 is loosened, the second spring 73 is not stressed any more, and the second spring 73 rebounds to enable the upper end of the baffle 71 to contact the inner rod 52, so that the infrared ray scanner 6 stops moving. When the infrared scanner 6 is required to be moved upward, the stay cord 45 is pulled to prevent the shutter 71 from coming into contact with the inner rod 52, and the inner rod 52 can be extended and contracted in length. When the direction parallel to the sliding groove 2 needs to be leveled, the other end of the pull rope 461 is pulled to enable the brake piece 47 to move towards the direction of the first spring 43, so that the brake piece 47 is not abutted against the rotating cylinder 41 any more, at this time, the first telescopic rod 3 is rotated, and the rotating cylinder 41 drives the first telescopic rod 3 to rotate. When the pull rope 461 is loosened when the first telescopic rod is adjusted to be in a proper position, the first spring 43 is not pressed 44 any more to rebound, the brake piece 43 returns to be in contact with the rotating cylinder 47, and the first telescopic rod 3 is not rotated. When the transverse distance needs to be adjusted, the first telescopic rod 3 is pulled, so that the infrared ray leveler 6 transversely moves to adapt to different directions.

The scheme has the beneficial effects that: the frame body 1 can drive the infrared scanner 6 to sweep the plane through the spliced chute 2 to adapt to different environment requirements; the first telescopic rod 3 is rotated to enable the first telescopic rod 3 to drive the infrared ray leveling instrument 6 to perform leveling in different directions; the first telescopic rod 3 can be fixed at different angles through the rotating device 46, so that the first telescopic rod 3 drives the infrared ray leveling instrument 6 to perform leveling at different angles; the infrared ray leveling instrument 6 can adjust the vertical height through the second telescopic rod 5 and the adjusting part 7, and meets the requirements of different heights; the rotation angle of the rotation device 4 and the vertical height of the adjusting part 7 to the second telescopic rod 5 can be controlled through the pull rope 45, so that the operation is more convenient.

Finally, it is noted that the above-mentioned preferred embodiments are only intended to illustrate rather than limit the utility model, and that, although the utility model has been described in detail by means of the above-mentioned preferred embodiments, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the scope of the utility model as defined by the appended claims.

Claims (5)

1. An infrared ray glance appearance alignment jig, its characterized in that: including support body (1), support body (1) upper end sliding connection has spout (2), spout (2) have the polylith concatenation to form, support body (1) lower part is connected with rotating device (4), rotating device (4) include: the infrared scanner comprises a rotating cylinder (41), a brake disc (47), a fixed shaft (42), a first spring (43), grooves (44) and a pull rope (45), wherein the bottom of a frame body (1) is fixedly connected with the fixed shaft (42), the inside of the fixed shaft (42) is hollow, the bottom of the frame body (1) is rotationally connected with the rotating cylinder (41), the rotating cylinder (41) is coated on the outer side of the fixed shaft (42), the grooves (44) are positioned on the inner side of the rotating cylinder (41), the brake disc (47) is positioned on two sides of the fixed shaft (42), the first spring (43) is positioned between the brake disc (47) and the fixed shaft (42), the pull rope (45) penetrates through the fixed shaft (42) to be connected with the brake disc (47), the other end of the rotating cylinder (41) is rotationally connected with a first telescopic rod (3), a second telescopic rod (5) is in ball joint with the other end of the first telescopic rod (3), a fixed block (46) is arranged on the outer side of the pull rope (45), a plurality of telescopic rods (3) and the other end of the telescopic rod (45) is connected with the second telescopic rod (5) respectively, and the other end of the telescopic rod (45) penetrates through the second telescopic rod (6).

2. The infrared scanner tuning fork as defined in claim 1, wherein: the second telescopic link (5) include interior pole (52) and outer pole (51), interior pole (52) be located outer pole (51) inside and with outer pole (51) sliding connection, second telescopic link (5) are connected with regulation portion (7) of adjusting second telescopic link (5) length, regulation portion (7) include: the rotary shaft (72), the second spring (73) and the baffle (71), the rotary shaft (72) is rotationally connected with the outer rod (51), the middle part of the baffle (71) is fixedly connected with the rotary shaft (72), the second spring (73) is located between the outer rod (51) and the baffle (71), and the other end of the pull rope (45) is connected with the lower end of the baffle (71).

3. The infrared scanner tuning fork as defined in claim 2, wherein: the baffle (71) is obliquely arranged, the upper end of the baffle (71) is in contact with the inner rod (52), and the bottom of the upper end of the baffle (71) is made of rubber.

4. The infrared scanner tuning fork as defined in claim 1, wherein: the pull rope (45) is arranged for the sections and is rotatably connected.

5. The infrared scanner tuning fork as defined in claim 1, wherein: the upper end of the frame body (1) is rotationally connected with a roller (8), and the roller (8) is in rolling connection with the chute (2).