CN206153024U - Spraying machine - Google Patents

Abstract

The utility model relates to a spraying machine, in particular to a spraying machine with more uniform spraying and higher spraying efficiency, which comprises a spraying system, a working platform, a PLC control system and a heating system, wherein the spraying system comprises a spray head with adjustable angle, and the spray head is connected on an X-axis sliding platform through a rotating mechanism; the X-axis sliding platform and the Z-axis sliding platform are connected in a sliding manner, the rotating mechanism is connected with the sample tray and drives the sample tray to rotate around the central shaft, a clamp is arranged on the sample tray and fixed with the sample tray, and the clamp is used for fixing a sample to be sprayed; the heating system comprises a heater and a temperature sensor, wherein the heater is arranged on the tray and is arranged in the curved surface sample. The utility model relates to a flush coater, adjustable shower nozzle that keeps is perpendicular relatively with the curved surface, when the shower nozzle spraying was incided, keeps the perpendicular incidence curved surface sample surface, has improved the homogeneity of spraying.

Description

a spraying machine

technical field

The invention relates to a spraying machine, in particular to a spraying machine with more uniform spraying and higher spraying efficiency.

Background technique

Most of the existing spraying methods are for flat products, and the entire spraying process is realized by moving the X, Y, and Z axes. The nozzle is relatively fixed, and there is no need to adjust the fixed position of the nozzle and the axis. When using the existing spraying method to spray the curved surface sample, the problem of uneven spraying will occur. As the nozzle moves along the axis, the nozzle and the curved surface sample will form a certain angle. When the spraying material is incident, it is incident on the curved surface at a certain angle. On the surface of the sample, it is easy to cause the place that needs to be sprayed not to be sprayed, and the thickness of the place to be sprayed is uneven; if the traditional spraying machine for spraying flat products is used to spray curved surface samples, it is easy to cause the spraying resin solution to flow in the direction of gravity. Thickness integration uncontrollable problem.

Contents of the invention

In order to overcome the deficiencies of the existing technology, this scheme designs a spraying machine that keeps the spray head relatively perpendicular to the curved surface at all times. When the spraying material is incident, it maintains a vertical incidence to the position where the surface of the curved surface sample needs to be sprayed, which improves the uniformity of spraying and at the same time Spraying at the temperature of the curved surface sample can prevent the liquid resin integrated on the surface from immediately adhering to the substrate surface, and improve the problem of uncontrollable thickness integration caused by the flow of the sprayed resin solution in the direction of gravity.

The specific technical scheme is as follows:

A spraying machine, including a spraying system, a working platform, a PLC control system,

The working platform includes an X-axis sliding platform, a Z-axis sliding platform, an X-axis sliding platform and a Z-axis sliding platform.

The platform is connected by sliding, and the X-axis sliding platform and the Z-axis sliding platform are respectively connected with motors;

Through the X-axis sliding platform or the Z-axis sliding platform, the movement along the outer contour curve of the substrate is realized.

The spraying system includes an angle-adjustable spray head, which is connected to an X-axis or Z-axis sliding platform through a rotating mechanism; specifically, the rotating mechanism is a Theta rotary motor or a rotatable manipulator.

The method to adjust the spraying position of the nozzle perpendicular to the surface of the curved sample is to obtain the coordinate point of the product to be tested, and obtain the angle between the nozzle and the X-axis sliding platform through curvature conversion, and control the angle of the nozzle through the PLC control system to make the nozzle spray The outgoing raw material is kept perpendicular to the position where the surface of the curved sample needs to be sprayed.

The PLC control system is used to control the trajectory of the nozzle, the X-axis sliding platform, and the Z-axis sliding platform.

Preferably: the X-axis sliding platform and the Z-axis sliding platform are slidingly connected through a well-shaped sliding groove.

Preferably: the spraying machine also includes a sample tray for placing samples and a rotating mechanism connected to the bottom of the sample tray.

Preferably: clamps for fixing curved samples are provided on the sample tray. The fixture is used to fix the sample to be sprayed so that the curved surface sample will not be thrown off during the rotation.

Preferably: the spraying machine also includes a heating system, the heating system includes a heater and a temperature sensor, the heater is installed on the tray and built into the sample, and the temperature sensor is connected to the PLC control system.

Preferably: the spraying machine also includes a material storage pressure tank, a feedback system, a spraying material supply device and a flow regulating device, the spraying material supply device is connected to the material storage pressure tank, the flow regulating device is connected to the material storage pressure tank, and the feedback system is connected to the material storage Pressure tank connection.

Preferably: the raw material ejected from the nozzle is a mist photosensitive resin. PLC control system is used to control spraying system and heating system.

The frame includes stainless steel door panels, spraying chambers, and exhaust systems.

The feedback system includes real-time feedback of the amount of glue in the glue storage pressure tank, which is used to connect and characterize the glue storage pressure tank glue volume system.

During assembly, the x-axis sliding platform and the z-axis sliding platform are slidably connected through a well-shaped sliding groove, and the x-axis sliding platform and the z-axis sliding platform are driven by a motor to move in translation. The spraying system is installed behind the x-axis. The spraying system includes a nozzle, The spraying raw material supply device and the flow regulating device realize the change of the angle between the nozzle and the X axis through the Theta rotary motor or the rotatable manipulator, so that the nozzle is perpendicular to the position where the surface of the curved sample needs to be sprayed to spray the raw material. The spraying raw material supply device is connected with the material storage pressure tank, the flow regulating device is connected with the material storage pressure tank, the PLC is connected with the spraying system and the heating system to control the spraying parameters and heating parameters, and the frame is connected with the X-axis\Z-axis sliding platform , the feedback system is connected with the storage pressure tank.

The spraying machine achieves uniform spraying, obtains the coordinate points of the curved surface product, determines the running track of the nozzle, and then translates the X-axis and Z-axis through the motor to realize the nozzle reaching the next point that needs to be sprayed, and adjusts the clip between the nozzle and the x-axis through the motor Angle, realize that the spray head is perpendicular to the tangent line of the surface spraying point, and keep spraying to spray glue with vertical incidence. Through the tray rotation mechanism, the curved surface samples are rotated in the tray to realize the process of comprehensive spraying. The nozzle sprays a mist of photosensitive resin. After spraying onto the curved surface, the heating system heats the surface of the curved sample. The misty photosensitive resin particles are integrated into the surface of the curved sample and adhere to heat, which can prevent the liquid resin integrated into the surface from sticking immediately. Attached to the surface of the substrate, improving the problem of uncontrollable thickness integration caused by the flow of the spray resin solution in the direction of gravity.

A kind of spraying method: comprise the following steps

Calculate the time that the nozzle stays on several contour surfaces of the curved surface sample;

Calculate the angle between the nozzle and the X-axis when the material ejected from the nozzle is perpendicular to the curved surface sample;

The PLC control system controls the stay time of the nozzle according to the calculated time data;

The PLC control system controls the angle of the nozzle according to the calculated angle data.

Preferably: a PLC control system is also included to control the heating of the heating system to heat the surface of the curved sample, integrate the sprayed raw material onto the surface of the curved sample, and adhere to the heated surface.

Preferably: it also includes the step of rotating the sample tray around the central axis by the rotating mechanism at the bottom of the sample tray. Let the curved surface sample rotate in the tray to realize the process of spraying all over.

Preferably: it also includes controlling the translation of the X-axis sliding platform and the Z-axis sliding platform, so that the nozzle can reach every position that needs to be sprayed;

The raw material ejected from the nozzle is a foggy photosensitive resin.

A spraying machine of the present invention can be adjusted to keep the spray head relatively perpendicular to the curved surface. When the spray head sprays and incidents, it keeps perpendicular to the surface of the curved surface sample, which improves the uniformity of spraying; at the same time, the heating system is used to increase the temperature of the curved surface sample for spraying, which can prevent The liquid resin integrated into the surface immediately adheres to the surface of the substrate, which improves the problem of uncontrollable thickness integration caused by the flow of the sprayed resin solution in the direction of gravity.

Description of drawings

Fig. 1 is a schematic diagram of the overall structure of a spraying machine of the present invention.

Fig. 2 is a schematic diagram of the bisection of the contour of the curved sample in the embodiment.

Fig. 3 is a schematic diagram of the angle of the spray head and the curved surface sample in the embodiment.

detailed description

The technical scheme of a spraying machine of the present invention will be described in further detail below in conjunction with the accompanying drawings.

As shown in Figure 1, a spraying machine includes a spraying system, a heating system, a working platform, a PLC control system, a rack, and a feedback system.

The spraying system includes a spray head 3, a spraying material supply device (not shown in the figure) and a flow regulating device (not shown in the figure). The spray head 3 moves along the curve of the outer contour of the substrate through the X-axis sliding platform 1 and the Z-axis sliding platform 2 .

The heating system includes a heater 5 and a temperature sensor. The heater 5 is installed on the tray 6 and built into the curved surface sample 4, so that the surface of the curved surface sample is evenly heated.

The working platform includes an X-axis sliding platform 1, a Z-axis sliding platform 2, a sample tray 6, a fixture (not shown in the figure), and a rotating mechanism 7. The rotating mechanism 7 is connected to the sample tray 6 to drive the sample tray 6 to rotate around the central axis. The sample tray 6 is provided with clamps, which are fixed to the sample tray 6, and the sample tray 6 is used to fix the product to be sprayed, so that the curved surface sample 4 will not be thrown off during the rotation.

The nozzle 3 is connected to the X-axis sliding platform 1 through the Theta rotation motor, and the curvature conversion of the specified coordinate point by the Theta rotation motor in the angular direction is perpendicular to the tangent.

PLC control system is used to control spraying system and heating system.

The frame includes stainless steel door panels, spraying chambers, and exhaust systems.

The feedback system is used for real-time feedback on the amount of glue in the glue storage pressure tank, and is used to connect and characterize the glue amount of the glue storage pressure tank.

During assembly, the X-axis sliding platform and the Z-axis sliding platform are slidably connected through a well-shaped sliding groove, and the X-axis sliding platform and the Z-axis sliding platform are driven by a motor to move in translation. The spraying system is installed at the rear of the X-axis. The spraying system includes nozzles, Spraying raw material supply device and flow regulating device, through the Theta rotary motor to realize the change of the angle between the nozzle and the X-axis, the spraying raw material supply device is connected to the material storage pressure tank, the flow regulating device is connected to the material storage pressure tank, PLC is connected to the spraying system and heating The device is connected to control the parameters of raw material spraying and heating, the frame is connected to the X\Z axis sliding platform, and the feedback system is connected to the material storage pressure tank.

The spraying machine achieves uniform spraying, obtains the coordinate points of the curved surface sample, determines the running track of the nozzle, and then translates the X-axis and Z-axis through the motor to realize the nozzle reaching the next point to be sprayed, and adjusts the clamp between the nozzle and the X-axis through the motor Angle, realize that the spray head is perpendicular to the tangent line of the surface spraying point, and keep spraying to spray glue with vertical incidence. Through the tray rotation mechanism, the curved surface samples are rotated in the tray to realize the process of comprehensive spraying. The nozzle sprays mist-like photosensitive resin. After spraying onto the surface of the curved surface, the heating system heats the surface of the curved surface sample, and the mist-like photosensitive resin particles are integrated into the surface of the curved surface sample and adhered to the heat.

A spraying method: comprises the following steps:

Calculate the time that the nozzle 3 stays on several contour surfaces of the curved sample 4;

Calculate the angle between the nozzle 3 and the X-axis when the material ejected by the nozzle 3 is perpendicular to the curved sample 4;

The PLC control system controls the time that the nozzle 3 stays above the curved surface sample 4 according to the calculated time data;

The PLC control system controls the angle of the nozzle 3 according to the calculated angle data.

Preferably: a PLC control system is also included to control the heating of the heating system to heat the surface of the curved sample 4, to integrate the sprayed material onto the surface of the curved sample 4, and to heat and adhere. The heating system can increase the temperature of the curved surface sample 4 for spraying, which can prevent the liquid resin integrated on the surface from immediately adhering to the substrate surface, and improve the problem of uncontrollable thickness integration caused by the flow of the sprayed resin solution in the direction of gravity.

Preferably: it also includes the step that the rotation mechanism 7 at the bottom of the sample tray 6 drives the sample tray 6 to rotate around the central axis. Let the curved surface sample 4 rotate in the tray 6 to realize the process of comprehensive spraying.

Preferably: it also includes controlling the translation of the X-axis sliding platform 1 and the Z-axis sliding platform 2, so that the spray head 3 reaches each position that needs to be sprayed;

The spray head 3 sprays the photosensitive resin whose raw material is mist.

The calculation method for the time that the nozzle 3 stays above the curved surface sample 4 is as follows:

The flow rate is Q, the spraying target thickness is H _, and the spraying time is T

The ratio of spraying raw materials is powder: solvent = 1:5, and the surface area to be sprayed is S _n

The volume of powder produced by the nozzle per unit time V=Q

Powder integration thickness per unit time H=V/6S _n

_{The total} time required to integrate the target thickness H of surface area S _n to be sprayed (residence time in each contour surface)

T _n ＝ _Htotal /H＝6S _n * _Htotal /Q................①

As shown in Figure 2: the surface structure is a hollowed-out geometry in the middle of a hemisphere and a cone

For hemispheres:

_The radius of the sphere is R, and the whole hemisphere is divided into N parts according to the integrated height H _of the nozzle falling to the spherical surface in the height direction, and the height direction _of the sphere is divided into N parts. .H _n , the surface area of each part is A ₁ , A ₂ , A ₃ .....A _n

According to the spherical crown surface area formula S=2πRH

can be pushed out

A ₁ =S ₁ =2πRH ₁

A ₂ =S ₂ -S ₁ =2πR(H ₂ -H ₁ )

A _n ＝S _n -S _n-1 ＝2πR(H _n -H _n-1 )

Substitute into ① to get hemisphere Tn=12πR(H _n -H _n-1 )H _total /Q

For the conical part, the radius of the bottom surface of each conical surface interface is R ₁ , R ₂ , R ₃ ...... R _n

The surface area of the conical expansion is S _n = πL(R _n +R _n-1 )

R _n‐1 : surface radius on the conical surface

R _n : Radius of the bottom surface of the conical surface

L: Conical busbar

The surface area of a single equal-height frustum B _n = πL(R _n +R _n-1 )

The residence time of each contour surface T _n '=6B _n *H _total /Q=6πLH _total (R _n +R _n-1 )/Q

If the radius of the hemisphere is 100mm, the radius of the bottom surface of the cone is 150mm, and the height of the cone is 130mm, the height of each contour surface is H=5mm.

Then the S and T values can be obtained as follows:

The following are theoretical values (without considering the influence of process)

When the raw material ejected by the nozzle 3 is perpendicular to the curved surface sample 4, the method of calculating the angle between the nozzle 3 and the X axis is as follows:

As shown in Figure 3, the angle between the nozzle and the horizontal X-axis is defined as the nozzle angle а.

The radius of the hemisphere is k, the slope of the cone generatrix is σ, and the coordinates of point B are (-k,-k)

Taking the apex of the hemisphere as the zero point of the coordinate axis, when calculating the nozzle angle, the hemisphere part is regarded as a parabola with an opening downward, and the cone part is regarded as a straight line with a certain slope. According to the above base size can be obtained:

The parabolic equation is: y=-kx ²

Linear equation: y=(σ-1)x

For any A on the parabola, the coordinates of A are (x _a ,-kx _a ² )

Tanа＝│x _a /y _a │＝│1/kx _a │

а＝arctan│1/kx _a │

For the cone slope is certain

а＝90-arctan│σ│

If the radius of the hemisphere is 100mm, the radius of the bottom surface of the cone is 150mm, the height of the cone is 130mm, and the height of each contour surface is H=5mm, the angle calculation is as follows:

Taking the fixed point of the hemisphere as the zero point of the coordinate axis, when calculating the nozzle angle, the part of the hemisphere is regarded as a parabola with an opening downward, and the part of the cone is regarded as a straight line with a certain slope. According to the above base size can be obtained:

The parabolic equation is: y=-x ² /100

Straight line equation: y=13x/5+130

For a parabola such as point A, the coordinates of A are (x,-x ² /100)

Tan(90-a)=y/x=100/x

а＝90-arctanx

For the cone slope is certain

а＝arctan(5/13)

A spraying machine of the present invention calculates the trajectory of the nozzle, adjusts the X axis to move up and down, left and right to reach the next predetermined trajectory point, adjusts the angle between the nozzle and the X axis, and realizes the vertical incidence of the nozzle and the curved surface tangent. The spraying machine of the present invention can spray more complex curved surface samples and keep the vertical incidence during the spraying process to achieve a uniform spraying process, and in the process of spraying, a heating system is provided under the curved surface samples to control the curved surface samples The increased temperature can prevent the liquid resin integrated into the surface from immediately adhering to the surface of the substrate, and prevent the thickness integration from being uncontrollable due to the flow of the sprayed resin solution in the direction of gravity. Finally, it should be noted that the above embodiments are only used to illustrate the technical solutions of the present invention, rather than to protect the present invention.

Although the invention has been described in detail with reference to the preferred embodiments, the general knowledge in the art

Those of ordinary skill in the art should understand that the technical solution of the present invention can be modified or equivalently replaced, and

Without departing from the spirit and scope of the technical solutions of the present invention.

Claims (6)

1. a spraying machine, is characterized in that: comprise spraying system, working platform, PLC control system, The working platform includes an X-axis sliding platform and a Z-axis sliding platform, the X-axis sliding platform and the Z-axis sliding platform are connected by sliding, and the X-axis sliding platform and the Z-axis sliding platform are respectively connected with motors; The spraying system includes an angle-adjustable spray head, which is connected to the X-axis sliding platform or the Z-axis sliding platform through a rotating mechanism; The PLC control system is used to control the trajectory of the nozzle, the X-axis sliding platform, and the Z-axis sliding platform. 2. A spraying machine according to claim 1, characterized in that: the X-axis sliding platform and the Z-axis sliding platform are slidingly connected by a well-shaped sliding groove. 3. A spraying machine according to claim 1, characterized in that: the spraying machine further comprises a sample tray for placing samples and a rotating mechanism connected to the bottom of the sample tray. 4. A spraying machine according to claim 1, characterized in that: the spraying machine further comprises a sample tray, on which a clamp for fixing a curved surface sample is arranged. 5. A kind of spraying machine according to claim 3, it is characterized in that: spraying machine also comprises heating system, and described heating system comprises heater and temperature sensor, and heater is installed on the pallet, is built in inside sample, and temperature sensor Connect with PLC control system. 6. A kind of spraying machine according to claim 1, characterized in that: the spraying machine also includes a material storage pressure tank, a feedback system, a spraying material supply device and a flow regulating device, and the spraying material supply device is connected with the material storage pressure tank, The flow regulating device is connected with the material storage pressure tank, and the feedback system is connected with the material storage pressure tank.