JP2714584B2 - Paint supply device - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a paint supply apparatus for controlling a flow rate of paint supplied from a paint supply source to a coating machine under pressure.

[Conventional technology]

For example, when painting with an air spray gun or airless spray gun, if you are trying to adjust the spray pattern by adjusting the discharge amount of paint, in the case of an air spray gun, adjust the opening of the paint supply valve. By changing the paint supply pressure, the discharge amount can be easily adjusted, but in the case of an airless spray gun, the paint discharge amount is determined by the paint supply pressure and the nozzle diameter, so if you try to adjust the discharge amount, There has been no method other than adjusting the supply pressure of the paint and changing the nozzle diameter by replacing the nozzle.

Therefore, the applicant has proposed a paint supply means using a flow control valve that can easily variably control the discharge amount without adjusting the paint supply pressure or replacing the nozzle regardless of the air spray gun or the airless spray gun. (Japanese Patent Application No. 1-165794, Japanese Patent Application No. 1-165795, and Japanese Patent Application No. 1-165796).

These are provided with a needle valve which is opened and closed by a solenoid coil in a paint flow path from a paint supply source to a nozzle of a coating machine, and a predetermined duty ratio and a predetermined duty ratio are provided in the coil in accordance with a paint flow rate. By supplying an energizing pulse having a pulse cycle, the needle valve is repeatedly opened and closed at a high frequency at a frequency corresponding to the cycle, and paint is discharged at a flow rate according to the energizing time to the solenoid coil.

Therefore, even when connected to an airless spray gun, by controlling the duty ratio and pulse period of the energizing pulse variably, the energizing time of the solenoid coil can be adjusted, and the discharge amount of the paint can be freely adjusted.

[Problems to be solved by the invention]

However, when the energizing pulse is supplied, the soleroid coil has electric resistance and generates heat when energized, and also generates heat due to a magnetic field change when the pulse is supplied to the coil.

In particular, if the paint supply pump breaks down or the nozzle is clogged, the paint, which also serves as a cooling element, loses heat during the distribution of the paint, so that the solenoid coil is likely to be overheated.

However, since such a flow control valve is used in an atmosphere containing an organic solvent, it is required that the operating temperature does not exceed a certain standard in any case, and the coil exceeds the standard. And high temperature (e.g. 100-120
C) are not allowed to be used.

In order to prevent overheating of the solenoid coil, it is possible to provide a temperature sensor on the coil and stop the supply of the energizing pulse based on the detection signal, but the temperature sensor such as a thermistor easily breaks down, A new problem arises in that at least two wires are required for driving the coil and for the signal line of the temperature sensor.

Therefore, the present invention has an object to divert the currently used flow control valve as it is and to keep the maximum temperature within a certain reference value even if the solenoid coil generates heat. It is an object to detect the temperature of a solenoid coil without using a sensor, and to stop supplying an energizing pulse when the temperature reaches a preset upper limit value.

[Means for solving the problem]

In order to solve this problem, the present invention relates to a paint supply device for controlling the flow rate of paint supplied from a paint supply source to a coating machine by feeding the paint flow path from the paint supply source to a nozzle of the painting machine. A flow control valve is interposed, the valve includes a needle valve urged in a valve closing direction in which a valve body is pressed against a valve seat by a spring, a movable core fixed to the needle valve, and the movable core. A solenoid coil that lifts up in the valve-opening direction against the elasticity of the spring, and changes a drive circuit that supplies an energizing pulse having a predetermined pulse cycle according to the flow rate of the paint to the coil by a heat generated by the coil. A resistance detector for detecting a resistance value to be detected based on the current and voltage of the energizing pulse is connected, and the detected resistance value is set to a preset upper limit temperature of the solenoid coil. Temperature of the coil based - upon reaching the upper limit resistance value determined from resistance function arithmetic unit for outputting a control signal for stopping the energization of the coil is characterized in that it is connected.

[Function of the invention]

When an energizing pulse is supplied to the solenoid coil of the flow control valve, the coil has an electric resistance, so that heat is generated by energizing the coil and heat is also generated by a magnetic field change caused by the supply of the energizing pulse, thereby increasing the electric resistance.

Then, when the solenoid coil reaches the upper limit temperature of the allowable temperature range, the resistance value is also reduced by the temperature of the coil.
The resistance reaches the upper limit value determined by the resistance function.

At this time, since the resistance value of the coil is detected from the current and voltage of the energizing pulse supplied to the solenoid coil, the heating state of the coil can be known without using a temperature sensor.

And when the detected resistance value reaches the upper limit resistance value,
Since it is determined that the coil has reached the upper limit temperature and the energization of the solenoid coil is stopped, the coil does not overheat any more and the maximum temperature can be kept within a certain reference value.

〔Example〕

Hereinafter, embodiments of the present invention will be specifically described with reference to the drawings.

FIG. 1 is a flow sheet showing an example of a paint supply device according to the present invention.

The paint supply device for controlling the flow rate of paint supplied from the paint supply source 12 to the coating machine G is a paint hose (paint flow path).
The flow control valve V includes a flow control valve V and an energization controller C for driving the flow control valve V.

The flow control valve V is connected between the paint inlet 1A and the paint outlet 1B.
A valve element 4 for opening and closing the paint passage 2 communicating with the valve valve 4 is pressed against a valve seat 6 by the elasticity of a spring 5 and is urged in a valve closing direction, and is fixed to the rear end side of the needle valve 3. The movable core 7 is opened and the needle valve 3 is opened against the elasticity of the spring 5 each time an energizing pulse whose duty ratio and pulse cycle are selected to predetermined values is input from the energizing controller C. And a solenoid coil 8 that lifts up in the valve direction.

The needle valve 3 is formed of a hollow pipe, and a valve body 4 is attached to a distal end side of the hollow pipe.
A paint outlet 3a that opens near the opening is formed, and the rear end side of the hollow pipe opens toward the paint inlet 1A.

The body 9 that guides the movable core 7 is provided with a stopper 11 that lifts up the movable core 7 and collides with the flange 10 of the needle valve 3 that has been fully opened. It is opened and closed by vibrating at a stroke corresponding to a gap provided between the stopper 10 and the stopper 11.

The flow control valve V is covered with an explosion-proof cover 14, and connectors 15A and 15B for connecting the paint hoses 13 are formed on both front and rear ends of the cover 14.

A connection terminal 17 of a lead 16 for connecting the solenoid coil 8 to the energization controller C is formed above the flow control valve V, and an energization pulse is supplied via the lead 16. .

The energization controller C includes a drive circuit 17 for transmitting an energization pulse having a predetermined duty ratio and a predetermined cycle according to the flow rate of the paint, and a current detector for detecting the current and voltage of the energization pulse transmitted from the drive circuit 17 18 and voltage detector 19
When, a resistor detector 20 for determining the resistance of the solenoid coil 8 based on the detected current and voltage, is detected resistance value, the coil 8 based on the preset upper temperature t _u
Temperature - when reaching the determined upper limit resistance value R _u by the resistance function, an operational unit 21 for outputting a control signal S _c for stopping the transmission of energizing pulse.

In the resistance detector 20, the resistance value R of the solenoid coil 8 at that time is determined based on the current I and the voltage V of the energizing pulse detected by the current detector 18 and the voltage detector 19.
_t (R _t = V / I) is calculated, and the calculation result is output to the arithmetic unit 21.

Resistance R _t Since changes depending on the temperature of the solenoid coil 8, by detecting the resistance value R _t, without using a separate temperature sensor, it is possible to know the heat generation state of the solenoid coil 8.

The arithmetic unit 21 includes a temperature-resistance function f of the coil 8.
(T) = R _t is stored, and when the upper limit temperature _tu is set, the upper limit resistance value corresponding to the upper limit temperature _tu is obtained from the function f (t).
R _u is calculated and stored.

Then, the resistance value R _t of the solenoid coil 8 upper resistance
Is compared with R _U, when the resistance value R _t reaches the upper limit resistance value R _U,
Control signal S _c for stopping the transmission of energizing pulse is output.

The temperature-resistance function f (t) representing the relationship between the temperature t of the solenoid coil 8 and the resistance value _Rt is expressed by the following equation.
The reference resistance at the reference temperature t ₀ (for example, t ₀ = 20 ° C.)
Assuming that R ₀ and the temperature coefficient are α, the following equation can be used.

f (t) = R _t = R ₀ [1 + α (t−t ₀ )] Further, the upper limit temperature _tu is selected according to a certain safety standard determined by the organic solvent contained in the paint to be used, and the upper limit resistance value R _u is from the above equation, calculated in R _u = R _{0 [1 + α (t u -t 0} ) ], and thus vary in accordance with the type of the organic solvent contained in the paint used.

When a switch (not shown) of the energization controller C is turned on, the drive circuit 17 sends the flow control valve V
An energizing pulse having a predetermined duty ratio and a predetermined pulse cycle according to the paint supply flow rate is output to the solenoid coil 8.

When an energizing pulse is input to the solenoid coil 8, the needle valve 3 repeatedly opens and closes at a high speed in accordance with the duty ratio and the pulse period. It is supplied at a flow rate.

Further, when the energizing pulse is supplied, the solenoid coil 8 has electric resistance and generates heat by energizing.
Heat is also generated due to a magnetic field change or the like caused by the supply of the energizing pulse, and its electric resistance increases, so that the current or voltage of the energizing pulse being supplied changes.

Current and voltage of the energizing pulse is detected by the current detector 18 and voltage detector 19, the resistance value R _t of the solenoid coil 8 on the basis of the current and voltage is detected by the resistance detector 20 in real time, the detection result It is input to the arithmetic unit 21.

The determining the arithmetic unit 21, the resistance value R _t of the solenoid coil 8 is compared with the upper limit resistance value R _U, it reaches the upper limit resistance value R _U, and the temperature of the solenoid coil 8 has reached the upper limit temperature t _u is, the drive circuit 17 from the arithmetic unit 21, output control signal S _C to stop the transmission of energizing pulses, the transmission of power pulses from the drive circuit 17 is stopped, the solenoid coil 8 exothermic more It can be kept within the safety standards even at the highest temperature.

In the embodiment, the case where the flow control valve V is interposed in the paint hose 13 is described. However, the present invention is not limited to this, and the flow control valve V is interposed in the paint flow path from the paint supply source to the nozzle of the coating machine G. If so, for example, it may be integrated into the coating machine G or integrated into a color change valve or the like.

Further, in the arithmetic unit 21, the detected resistance value _Rt is
Although only the case of comparison with the upper limit resistance value R _U has been described,
From the resistance value R _t to calculate the temperature t, it may be a case of comparing the temperature and the upper limit temperature t _u.

Furthermore, when a constant-voltage power supply is used, the resistance can be obtained by detecting the current without detecting the voltage. In this case, there is no need to provide a voltage detector.

〔The invention's effect〕

As described above, according to the present invention, when the solenoid coil of the flow rate control valve generates heat and its resistance value reaches the upper limit resistance value, the energization is stopped, and further temperature rise is prevented, It has an excellent effect that the maximum temperature can be kept within a certain allowable range.

Moreover, since the heat generation state of the coil is detected based on the resistance value of the coil based on the current and voltage of the energizing pulse, there is no need to provide a separate temperature sensor, and the apparatus currently used is directly used. There is also an effect that it can be diverted.

[Brief description of the drawings]

 FIG. 1 is a flow sheet showing an embodiment of the present invention. Description of symbols G: coating machine, V: flow control valve, 1A: inlet, 1B: outlet, 3: needle valve, 4: valve body, 5: spring, 6: valve seat , 7: movable core, 8: solenoid coil, 12: paint supply source, 13: paint hose (paint flow path), C: energization controller, 17: drive circuit 18: current detector, 19 ... voltage detector, 20 ... resistance detector, 21 ... arithmetic unit. 4

Continuation of the front page (56) References JP-A-2-57816 (JP, A) JP-A-61-111163 (JP, A) JP-A-3-30856 (JP, A) JP-A-3-30857 (JP) JP-A-3-30855 (JP, A) JP-A-58-31065 (JP, U)

Claims (1)

(57) [Claims] A paint supply device for controlling a flow rate of paint supplied from a paint supply source (12) to a coating machine (G) from a paint supply source (12) to a nozzle of the coating machine (G). A flow control valve (V) is interposed in the paint flow path (13). The valve (V) is attached in a valve closing direction in which a valve body (4) is pressed against a valve seat (6) by a spring (5). The biased needle valve (3), the movable core (7) fixed to the needle valve (3), and the movable core (7) are moved in the valve opening direction against the elasticity of the spring (5). A solenoid coil (8) that lifts up; a drive circuit (17) that supplies an energizing pulse having a predetermined pulse cycle according to the flow rate of the paint to the coil (8); Resistance based on the current and voltage of the energizing pulse. With detector (20) is connected, the detected resistance value, the coil based on the upper temperature limit of a preset solenoid coil (8) (8)
When the temperature reaches the upper resistance value obtained from the temperature-resistance function,
An apparatus for supplying a paint, characterized in that an arithmetic unit (21) for outputting a control signal for stopping energization of the coil (8) is connected.