A feeding machine for wood floor processing
By introducing a limiting mechanism consisting of slide rails, slide blocks, synchronous seats, rollers, laser sensors, and electro-hydraulic actuators into the feeding device, the problem of feeding deviation of wooden flooring was solved, realizing automatic limiting and stable feeding of different types of flooring, and improving the applicability and intelligence of the equipment.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- DALIAN AMUER WOOD CO LTD
- Filing Date
- 2025-06-19
- Publication Date
- 2026-06-16
Smart Images

Figure CN224361987U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of wood flooring processing technology, specifically a feeding machine for wood flooring processing. Background Technology
[0002] Wooden flooring refers to flooring made of wood. Based on material, it can be divided into solid wood flooring, engineered wood flooring, and laminate flooring. During the processing of wooden flooring, a conveyor system is used to feed and process the wood. In existing technology: [Authorization Publication No. CN 213255333] U's patent discloses a feeding device for composite flooring processing, including an operating table, a chute, and a telescopic rod. A shaped rod is fixedly connected to the top of the telescopic rod, and a fixing block is fixedly connected to one end of the shaped rod. A rotating shaft is inserted into one side of the fixing block, and one end of the rotating shaft is fixedly connected to the side of a fixing ring. The painting equipment in this feeding device is placed inside the fixing ring. Rotating the handle moves the extrusion plate downwards, extruding and fixing the painting equipment, avoiding fatigue caused by prolonged hand-holding of the painting equipment and reducing work efficiency. The fixing ring's tilt angle can be adjusted by the rotating shafts on both sides, and it is fixed by a threaded ring in a compression manner, facilitating adjustment of the spraying tilt angle when placing composite flooring on the operating table surface. An auxiliary roller can rotate while dragging the composite flooring, making dragging more effortless and convenient. This device uses the auxiliary roller to transport the wood flooring. However, the auxiliary roller lacks limiting components, causing feeding deviation when the wood flooring moves on the auxiliary roller. Therefore, we propose a feeding machine for wood flooring processing. Utility Model Content
[0003] The technical problem to be solved by this utility model is to overcome the existing defects and provide a feeding machine for wood flooring processing. This device can automatically limit the offset of the wood flooring feeding, and the limiting component of the device can be adjusted according to the size of the wood flooring itself, so that the device is suitable for anti-offset operation of feeding various types of wood flooring. The equipment is convenient and intelligent to use and can effectively solve the problems in the background art.
[0004] To achieve the above objectives, the present invention provides the following technical solution: a feeding machine for processing wood flooring, including a feeding table, two horizontally symmetrically distributed connecting seats on the upper side of the feeding table, and a uniformly distributed feeding roller rotatably connected between the opposite inner sides of the two connecting seats through a bearing, and also includes a limiting mechanism.
[0005] The limiting mechanism includes a slide rail, a slide base, a synchronous seat, a roller, a laser sensor, an electro-hydraulic actuator, and a vertical limiting component. The slide rails are respectively set on the front and rear sides of the upper left and right ends of the feeding platform. A slide base is slidably connected between each pair of longitudinally adjacent slide rails. A synchronous seat is provided on the upper side of each slide base. Rollers are evenly distributed and rotatably connected to the grooves on the opposite inner sides of the two slide bases through bearings. Electro-hydraulic actuators are provided on the opposing surfaces of the two front slide rails. The telescopic ends of the electro-hydraulic actuators are fixedly connected to the adjacent slide bases. Laser sensors are provided on the opposing surfaces of the two slide bases. A vertical limiting component is provided on each synchronous seat. This device can automatically limit the offset of the wood flooring processing feed. The limiting components of the device can be adjusted according to the size of the wood flooring itself, making the device suitable for anti-offset operations of various types of wood flooring processing feed. The overall equipment is convenient and intelligent to use.
[0006] Furthermore, it also includes a microcontroller, which is located outside the feeding platform. The input terminal of the microcontroller is electrically connected to an external power supply, and the output terminal of the microcontroller is electrically connected to the input terminal of the electro-hydraulic actuator. The laser sensor is also bidirectionally electrically connected to the microcontroller, which facilitates the control of the electrical components in the device.
[0007] Furthermore, it also includes motors, which are respectively located at the front and rear ends of the right side of the connecting seat on the right side. The input ends of the motors are electrically connected to the output ends of the microcontroller. The right ends of the frontmost and rearmost feeding rollers are fixedly connected to the output shafts of the adjacent motors, providing power for the device to feed the wood flooring.
[0008] Furthermore, the vertical limiting assembly includes two electro-hydraulic actuators, a lifting seat, a U-shaped seat, two rollers, two laser sensors, and one guide rod. The two electro-hydraulic actuators are respectively located on the upper middle part of the synchronous seat. The input end of each of the two electro-hydraulic actuators is electrically connected to the output end of the microcontroller. The telescopic end of each of the two electro-hydraulic actuators is provided with a lifting seat. The lower side of each lifting seat is provided with evenly distributed U-shaped seats. The inside of each U-shaped seat is rotatably connected to the rollers through bearings. The upper side of each lifting seat is provided with a laser sensor and two longitudinally symmetrically distributed guide rods. The laser sensors are bidirectionally electrically connected to the microcontroller. The upper end of each guide rod is slidably connected to a circular hole on the adjacent synchronous seat to limit the vertical movement of the wooden flooring processing feed.
[0009] Furthermore, a connecting frame is provided at the upper rear end of the feeding platform, and an electro-hydraulic actuator three is provided at the upper middle part of the connecting frame. The input end of the electro-hydraulic actuator three is electrically connected to the output end of the microcontroller. A stop seat is provided at the telescopic end of the electro-hydraulic actuator three. Two symmetrically distributed guide rods two are provided on the upper side of the stop seat. The upper ends of the guide rods two are slidably connected to the round holes two opened in the top wall of the connecting frame to limit the movement of the wood flooring processing in the feeding machine for wood flooring processing.
[0010] Furthermore, a pressure sensor is installed between the telescopic end of the electro-hydraulic actuator three and the upper middle part of the stop seat. The pressure sensor is bidirectionally electrically connected to the microcontroller to measure and upload the limiting extrusion force applied to the wooden floor by the stop seat in the wooden flooring feeder.
[0011] Furthermore, a rubber sheet is provided on the lower side of the stop seat to increase the contact friction between the stop seat and the wooden floor in the feeder for processing wooden flooring.
[0012] Compared with the prior art, the beneficial effects of this utility model are as follows: This feeding machine for processing wood flooring has the following advantages:
[0013] When using the wood flooring processing feeder, rollers one and two can automatically limit the offset of the wood flooring feeding. The rollers of the device, through slide rails, slide seats, synchronous seats, laser sensor one, electro-hydraulic actuator one and vertical limit components, can adjust their positions according to the size of the wood flooring itself, making the device suitable for anti-offset operation of various types of wood flooring processing and feeding. The overall equipment is convenient and intelligent to use. Attached Figure Description
[0014] Figure 1 This is a schematic diagram of the structure of this utility model;
[0015] Figure 2 This is an enlarged structural diagram of point A in this utility model;
[0016] Figure 3 This is an enlarged structural diagram of section B of the present invention.
[0017] In the diagram: 1. Feeding platform, 2. Microcontroller, 3. Connecting seat, 4. Feeding roller, 5. Motor, 6. Limiting mechanism, 61. Slide rail, 62. Slide seat, 63. Synchronous seat, 64. Roller I, 65. Laser sensor I, 66. Electro-hydraulic actuator I, 67. Vertical limiting assembly, 671. Electro-hydraulic actuator II, 672. Lifting seat, 673. U-shaped seat, 674. Roller II, 675. Laser sensor II, 676. Guide rod I, 7. Connecting frame, 8. Electro-hydraulic actuator III, 9. Stop seat, 10. Rubber sheet, 11. Pressure sensor, 12. Guide rod II. Detailed Implementation
[0018] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0019] Please see Figure 1-3This embodiment provides a technical solution: a feeding machine for processing wood flooring, including a feeding platform 1, with two horizontally symmetrically distributed connecting seats 3 on the upper side of the feeding platform 1. The inner surfaces of the two connecting seats 3 are rotatably connected by a bearing to uniformly distributed conveying rollers 4. The machine also includes a microcontroller 2, which is located outside the feeding platform 1. The input end of the microcontroller 2 is electrically connected to an external power source. The machine also includes motors 5, which are respectively located at the front and rear ends of the right side of the connecting seat 3. The input ends of the motors 5 are electrically connected to the output ends of the microcontroller 2. The right ends of the frontmost and rearmost conveying rollers 4 are fixedly connected to the output shafts of the adjacent motors 5. The microcontroller 2 starts the two motors 5 so that their output shafts drive the corresponding conveying rollers 4 to rotate in the forward direction. The wood flooring is conveyed from front to back through the contact friction between the rotating conveying rollers 4 and the lower side of the wood flooring. The machine also includes a limiting mechanism 6.
[0020] Limiting mechanism 6 includes a slide rail 61, a slide base 62, a synchronization seat 63, rollers 64, a laser sensor 65, an electro-hydraulic actuator 66, and a vertical limiting component 67. The slide rails 61 are respectively located on the front and rear sides of the upper left and right ends of the feeding platform 1. A slide base 62 is slidably connected between each pair of longitudinally adjacent slide rails 61. A synchronization seat 63 is provided on the upper side of each slide base 62. Rollers 64 are evenly distributed and rotatably connected to the grooves on the opposite inner surfaces of the two slide bases 62 via bearings. Electro-hydraulic actuators 66 are provided on the opposing surfaces of the two front slide rails 61. The telescopic ends of the electro-hydraulic actuators 66 are fixedly connected to the adjacent slide base 62. Laser sensors 65 are provided on the opposing surfaces of the two slide bases 62. Each synchronization seat 63 is equipped with... The vertical limiting component 67 includes an electro-hydraulic actuator 671, a lifting seat 672, a U-shaped seat 673, a roller 674, a laser sensor 675, and a guide rod 676. The electro-hydraulic actuator 671 is located on the upper center of the synchronization seat 63. The input ends of the electro-hydraulic actuator 671 are electrically connected to the output ends of the microcontroller 2. The telescopic ends of the electro-hydraulic actuator 671 are equipped with lifting seats 672. The lower side of each lifting seat 672 has evenly distributed U-shaped seats 673. The interior of each U-shaped seat 673 is rotatably connected to rollers 674 via bearings. The upper side of each lifting seat 672 is equipped with... The device consists of a laser sensor 675 and two longitudinally symmetrically distributed guide rods 676. The laser sensor 675 is bidirectionally electrically connected to the microcontroller 2. The upper ends of the guide rods 676 are slidably connected to circular holes on adjacent synchronous seats 63. The vertical distance between the lower outer end of the roller 674 at its initial position and the upper outer end of the feed roller 4, as well as the initial lateral distance between two adjacent rollers 64, are transmitted to the microcontroller 2. When the device processes and feeds the wooden flooring, the wooden flooring is placed above the feed roller 4. The operator then inputs the width and thickness data of the wooden flooring into the microcontroller 2. Based on the width data of the wooden flooring, the microcontroller 2 simultaneously activates the two electro-hydraulic actuators 66, causing them to extend and retract. The end drives the corresponding slide block 62 to move along the slide rail 61 towards the lateral center of the device. At the same time, the microcontroller 2 activates the laser sensor 65, which emits a light signal that shines onto the wall of the corresponding slide rail 61 and reflects back to the initial position. Based on the propagation time and speed of the light signal, the lateral movement distance of the slide block 62 along the slide rail 61 is measured, and the measurement result is transmitted to the microcontroller 2 as an electrical signal. The microcontroller 2 controls the extension length of the telescopic end of the electro-hydraulic actuator 66 based on the width data of the wooden floor, the initial lateral distance between two horizontally adjacent rollers 64, and the measured lateral movement distance of the slide block 62. This allows the rollers 64 on both sides to automatically perform lateral centering and limiting of the wooden floor conveyor.Subsequently, the microcontroller 2 activates the electro-hydraulic actuator 671, causing its telescopic end to move the corresponding lifting seat 672 vertically downwards. The lifting seat 672, via the U-shaped seat 673, drives the roller 674 to move vertically downwards synchronously (during the vertical movement of the lifting seat 672, the guide rod 676 adaptively slides along the corresponding circular hole, improving the vertical stability of the lifting seat 672 through the sliding guide between the two). Simultaneously, the microcontroller 2 activates the laser sensor 675, which emits a light signal that illuminates the lower side of the synchronous seat 63 and reflects back to the initial position. Using the same principle, the downward movement distance of the lifting seat 672 is measured, and the measurement result is transmitted to the microcontroller 2 as an electrical signal. The microcontroller 2 then adjusts the signal based on the characteristics of the wooden flooring. The vertical distance between the lower outer end of roller 674 (thickness data and initial position) and the upper outer end of the conveying roller 4, combined with the downward movement distance of the lifting seat 672, controls the movement distance of the telescopic end of the electro-hydraulic push rod 671. This allows the lower outer end of roller 674 to automatically press against the upper side of the wooden floorboard, thus automatically limiting the vertical offset of the wooden floorboard conveyor and improving the stability of the wooden floorboard feeding movement. This device can automatically limit the offset of the wooden floorboard processing feed, and the limiting components of the device can be adjusted according to the size of the wooden floorboard itself, making the device suitable for anti-offset operations of various types of wooden floorboard processing feed. The overall equipment is convenient and intelligent to use.
[0021] The feeding platform 1 has a connecting frame 7 at its upper rear end. An electro-hydraulic actuator 8 is located in the middle of the upper side of the connecting frame 7. The input end of the electro-hydraulic actuator 8 is electrically connected to the output end of the microcontroller 2. A stop seat 9 is located at the telescopic end of the electro-hydraulic actuator 8. Two symmetrically distributed guide rods 12 are located on the upper side of the stop seat 9. The upper ends of the guide rods 12 are slidably connected to the circular holes 2 opened in the top wall of the connecting frame 7. A pressure sensor 11 is installed between the telescopic end of the electro-hydraulic actuator 8 and the middle of the upper side of the stop seat 9. The pressure sensor 11 is bidirectionally connected to the microcontroller 2. Electrical connection; a rubber sheet 10 is provided on the lower side of the stop seat 9. When the wooden floorboard is conveyed to a certain length and processing is stopped, the microcontroller 2 shuts down the motor 5 and starts the electro-hydraulic push rod 8. The telescopic end of the electro-hydraulic push rod 8 drives the stop seat 9 to move vertically downward, thereby squeezing and limiting the upper surface of the wooden floorboard in this part (during the vertical movement of the stop seat 9, the guide rod 12 is driven to slide adaptively along the corresponding circular hole 2, and the vertical movement stability of the stop seat 9 is improved by the sliding connection between the guide rod 12 and the circular hole 2). The lower side of the stop seat 9 The rubber sheet 10 increases the contact friction between itself and the wooden floor, improving the fixing effect on the wooden floor. During this process, the microcontroller 2 activates the pressure sensor 11. The pressure sensor 11 is a piezoresistive pressure sensor, which is a sensor made using the piezoresistive effect of single-crystal silicon material and integrated circuit technology. The pressure sensor 11 is fixed to the telescopic end of the electro-hydraulic push rod 8. The detection end (single-crystal silicon wafer) of the pressure sensor 11 is fixedly connected to the upper middle part of the stop seat 9. When the stop seat 9 comes into contact with the wooden floor, the resistivity of the single-crystal silicon material changes under the action of force. The measuring circuit can obtain an electrical signal output proportional to the force change, thereby obtaining the extrusion force between the stop seat 9 and the wooden floor. This result is transmitted to the microcontroller 2 in the form of an electrical signal. When the extrusion force value between the stop seat 9 and the wooden floor obtained by the microcontroller 2 reaches a certain level, the microcontroller 2 promptly closes the electro-hydraulic push rod 8, so that the stop seat 9 can be used for fixing operations after the feeding of wooden flooring of different thicknesses stops, making it convenient to use.
[0022] The working principle of the feeding machine for processing wooden flooring provided by this utility model is as follows: The vertical distance between the lower outer end of the roller 674 at the initial position and the upper outer end of the conveying roller 4, as well as the initial horizontal distance between two adjacent rollers 64, are transmitted to the microcontroller 2. When the device is used to process and feed the wooden flooring, the wooden flooring is placed above the conveying roller 4. Then, the operator inputs the width and thickness data of the wooden flooring into the microcontroller 2. The microcontroller 2 simultaneously activates two electro-hydraulic actuators 66 according to the width data of the wooden flooring, so that the telescopic ends of the electro-hydraulic actuators 66 drive the corresponding slide block 62 to move along the slide rail 61 towards the horizontal center of the device. At the same time, the microcontroller 2 activates the laser sensor 65. Device 65 emits a light signal that illuminates the wall of the corresponding slide rail 61 and is reflected back to its initial position. Based on the propagation time and speed of the light signal, the lateral movement distance of the slide block 62 along the slide rail 61 is measured, and the measurement result is transmitted to the microcontroller 2 as an electrical signal. The microcontroller 2 controls the extension length of the telescopic end of the electro-hydraulic actuator 66 based on the width data of the wooden floor, the initial lateral distance between two horizontally adjacent rollers 64, and the measured lateral movement distance of the slide block 62. This allows the rollers 64 on both sides to automatically perform lateral centering and limiting of the wooden floor conveying. Subsequently, the microcontroller 2 activates the electro-hydraulic actuator 671, causing its telescopic end to drive the corresponding lifting seat 672 to move vertically downward. The lifting seat 672 moves vertically downward through the U-shaped seat. 673 drives roller 674 to move vertically downwards synchronously (during the vertical movement of lifting seat 672, guide rod 676 slides adaptively along the corresponding circular hole, thereby improving the vertical stability of lifting seat 672 through sliding guidance between the two). Simultaneously, microcontroller 2 activates laser sensor 675, which emits a light signal that illuminates the lower side of synchronous seat 63 and reflects back to the initial position. Using the same principle, the downward movement distance of lifting seat 672 is measured, and the measurement result is transmitted to microcontroller 2 as an electrical signal. Microcontroller 2, based on the thickness data of the wooden flooring and the vertical distance between the lower outer end of roller 674 at the initial position and the upper outer end of the conveying roller 4, combined with the downward movement distance of lifting seat 672, adjusts the electro-hydraulic push... The movement distance of the telescopic end of lever 671 is controlled, so that the lower outer end of roller 674 can automatically press against the upper side of the wooden floor, thereby automatically limiting the vertical offset of the wooden floor conveying. When the device processes and feeds wooden flooring, it can automatically limit the lateral and vertical offset of wooden flooring of different sizes, improving the stability of the wooden flooring feeding movement. It is intelligent and convenient to use. Then, the microcontroller 2 starts the two motors 5, so that their output shafts drive the corresponding conveying rollers 4 to rotate in the forward direction. The contact friction between the rotating conveying rollers 4 and the lower side of the wooden flooring conveys the wooden flooring from front to back. When the wooden flooring is conveyed to a certain length and processing is stopped, the microcontroller 2 shuts down the motors 5 and starts the electro-hydraulic push rod 8.The telescopic end of the electro-hydraulic actuator 8 drives the stop seat 9 to move vertically downward, thereby squeezing and limiting the upper surface of the wooden floor in this area (during the vertical movement of the stop seat 9, the guide rod 12 slides adaptively along the corresponding circular hole 2, and the vertical stability of the stop seat 9 is improved through the sliding connection between the guide rod 12 and the circular hole 2). The lower side of the stop seat 9 increases the contact friction between itself and the wooden floor through the rubber sheet 10, thereby improving the fixing effect on the wooden floor. During this process, the microcontroller 2 activates the pressure sensor 11. The pressure sensor 11 is a piezoresistive pressure sensor, which is a sensor made using the piezoresistive effect of single-crystal silicon material and integrated circuit technology. The pressure sensor 11 is fixed to the electro-hydraulic actuator. On the telescopic end of the three-electro-hydraulic actuator 8, the detection end (monocrystalline silicon wafer) of the pressure sensor 11 is fixedly connected to the upper center of the stop seat 9. When the stop seat 9 comes into contact with the wooden floorboard, the resistivity of the monocrystalline silicon material changes under the action of force. The measuring circuit outputs an electrical signal proportional to the force change, thus obtaining the pressure between the stop seat 9 and the wooden floorboard. This result is transmitted to the microcontroller 2 as an electrical signal. When the pressure value between the stop seat 9 and the wooden floorboard obtained by the microcontroller 2 reaches a certain level, the microcontroller 2 promptly closes the electro-hydraulic actuator 8. This allows the stop seat 9 to be used for fixing wooden floorboards of different thicknesses after feeding has stopped, making it convenient to use.
[0023] It is worth noting that the microcontroller 2 disclosed in the above embodiments can be an MCS-51, the motor 5 can be a D140TYD, the laser sensor 65 and the laser sensor 675 can both be EE-SB5-B reflective photoelectric sensors, the electro-hydraulic actuator 66, the electro-hydraulic actuator 671 and the electro-hydraulic actuator 8 can all be DYZW integral straight micro electro-hydraulic actuators, and the pressure sensor 11 can be an HT12 silicon piezoresistive pressure sensor. The microcontroller 2 controls the operation of the motor 5, the laser sensor 65, the laser sensor 675, the electro-hydraulic actuator 66, the electro-hydraulic actuator 671, the electro-hydraulic actuator 8 and the pressure sensor 11 using methods commonly used in the prior art.
[0024] The above description is merely an embodiment of this utility model and does not limit the patent scope of this utility model. Any equivalent structural or procedural transformations made based on the content of this utility model specification and drawings, or direct or indirect applications in other related technical fields, are similarly included within the patent protection scope of this utility model.
Claims
1. A feeding machine for processing wood flooring, comprising a feeding table (1), wherein two transversely symmetrically distributed connecting seats (3) are provided on the upper side of the feeding table (1), and uniformly distributed feeding rollers (4) are rotatably connected between the opposite inner surfaces of the two connecting seats (3) via bearings, characterized in that: It also includes a limiting mechanism (6); Limiting mechanism (6): It includes a slide rail (61), a slide seat (62), a synchronizing seat (63), a roller (64), a laser sensor (65), an electro-hydraulic actuator (66), and a vertical limiting component (67). The slide rails (61) are respectively set on the front and rear sides of the left and right ends of the upper side of the feeding table (1). A slide seat (62) is slidably connected between two longitudinally adjacent slide rails (61). A synchronizing seat (63) is provided on the upper side of each slide seat (62). The grooves on the inner sides of the two slides (62) are connected by bearings to evenly distributed rollers (64). The opposing surfaces of the two slide rails (61) on the front side are provided with electro-hydraulic actuators (66). The telescopic ends of the electro-hydraulic actuators (66) are fixedly connected to the adjacent slides (62). The opposing surfaces of the two slides (62) are provided with laser sensors (65). The synchronizing seat (63) is provided with vertical limiting components (67).
2. The feeding machine for processing wooden flooring according to claim 1, characterized in that: It also includes a microcontroller (2), which is located outside the feeding table (1). The input end of the microcontroller (2) is electrically connected to an external power supply, and the output end of the microcontroller (2) is electrically connected to the input end of the electro-hydraulic push rod (66). The laser sensor (65) is bidirectionally electrically connected to the microcontroller (2).
3. The feeding machine for processing wooden flooring according to claim 2, characterized in that: It also includes a motor (5), which is respectively set at the front and rear ends of the right side of the connecting seat (3) on the right side. The input end of the motor (5) is electrically connected to the output end of the microcontroller (2). The right ends of the feed rollers (4) on the frontmost and rearmost sides are fixedly connected to the output shaft of the adjacent motor (5).
4. The feeding machine for processing wooden flooring according to claim 2, characterized in that: The vertical limiting component (67) includes an electro-hydraulic actuator two (671), a lifting seat (672), a U-shaped seat (673), a roller two (674), a laser sensor two (675), and a guide rod one (676). The electro-hydraulic actuator two (671) is respectively located on the upper middle part of the synchronous seat (63). The input end of the electro-hydraulic actuator two (671) is electrically connected to the output end of the microcontroller (2). The telescopic end of the electro-hydraulic actuator two (671) is provided with a lifting seat (672). The lower side of (672) is provided with uniformly distributed U-shaped seats (673). The interior of each U-shaped seat (673) is rotatably connected to rollers (674) through bearing three. The upper side of each lifting seat (672) is provided with a laser sensor (675) and two longitudinally symmetrically distributed guide rods (676). The laser sensor (675) is bidirectionally electrically connected to the microcontroller (2). The upper end of each guide rod (676) is slidably connected to a circular hole on the adjacent synchronous seat (63).
5. A feeding machine for processing wood flooring according to claim 2, characterized in that: The upper rear end of the feeding platform (1) is provided with a connecting frame (7). The middle part of the upper side of the connecting frame (7) is provided with an electro-hydraulic push rod three (8). The input end of the electro-hydraulic push rod three (8) is electrically connected to the output end of the microcontroller (2). The telescopic end of the electro-hydraulic push rod three (8) is provided with a stop seat (9). The upper side of the stop seat (9) is provided with two symmetrically distributed guide rods two (12). The upper ends of the guide rods two (12) are slidably connected to the round hole two opened on the top wall of the connecting frame (7).
6. A feeding machine for processing wood flooring according to claim 5, characterized in that: A pressure sensor (11) is installed between the telescopic end of the electro-hydraulic actuator (8) and the upper middle part of the stop seat (9). The pressure sensor (11) is bidirectionally electrically connected to the microcontroller (2).
7. A feeding machine for processing wood flooring according to claim 5, characterized in that: A rubber sheet (10) is provided on the lower side of the stop seat (9).