JP2014100114A - Sprayer - Google Patents

Abstract

[PROBLEMS] In a sprayer used for farm work or the like, when the conventional nozzle opening / closing valve is closed, the spray liquid discharged from the discharge pump is returned to the storage tank side, so that the spray liquid is circulated unnecessarily and consumed. There was a problem of increasing power.
An operation mode (suppression of power consumption) that stops the discharge pump P when the pressure in the flow path 25 becomes a constant pressure with the nozzle switching valve 34 closed, and the discharge pump P is driven as it is. The power supply circuit 50 is provided with a mode changeover switch 55 for selecting an operation mode (circulation in the tank 10) for circulating the spray liquid.
[Selection] Figure 11

Description

  The present invention relates to a sprayer used for spraying (spreading) medicines such as herbicides and disinfectants in horticultural work, for example.

For example, a technique relating to a so-called shoulder-type sprayer is disclosed in the following patent document. As shown in FIG. 21, this type of sprayer 100 includes a storage tank 101 that stores a spray liquid such as a medicine, and a drive unit 102 that includes a discharge pump P that pumps the spray liquid in the storage tank 101, A spray nozzle 103 that is attached to the tip of a hose drawn out from the drive unit 102 and that actually sprays the spray liquid is provided. Usually, the storage tank 101 is integrated with the drive part 102, for example, a user carries on the back. The spray nozzle 103 is held by a user to perform a spraying operation. When the power switch of the drive unit 102 is turned on, the discharge pump P is activated and the spray liquid is pumped from the storage tank 101 toward the spray nozzle 103. A manually operated nozzle opening / closing valve 104 is attached to the spray nozzle 103 held by one hand of the user. When the nozzle opening / closing valve 104 is opened, the spray liquid is sprayed from the discharge port.
In this type of sprayer 100, the discharge pump P is provided with an engine pump using an internal combustion engine as a drive source and an electric pump using an electric motor as a drive source. As the electric pump, an AC motor drive type using an AC power source as a power source and a DC motor type using a DC power source such as a battery pack as a power source are provided.
Further, in this type of sprayer 100, when the nozzle opening / closing valve 104 at the hand is opened, the spray liquid is sprayed from the discharge port as described above. When the nozzle opening / closing valve 104 is closed, spraying of the spray liquid at the discharge port is stopped. When the nozzle opening / closing valve 104 is closed while the discharge pump P is in operation, the spray liquid pumped from the discharge pump P is returned to the storage tank 101 via the return hose 105 without being sprayed from the spray nozzle 103. In this way, the spray liquid is circulated during non-spraying to prevent precipitation of the spray liquid components in the storage tank 101. Further, by setting the standby state in which the spray liquid is circulated, the spray liquid is quickly sprayed from the spray nozzle 103 when the nozzle opening / closing valve 104 is opened next time, so that a quick spraying operation can be performed. In this respect, the usability of the sprayer 100 can be improved.

Japanese Patent Laid-Open No. 2005-118674 JP 2006-15208 A

However, the conventional sprayer 100 has the following problems. As described above, in the conventional sprayer 100, when the nozzle opening / closing valve 104 is closed when the discharge pump P is activated, the spray liquid is circulated through the discharge pump P. Even in a state where the fuel is not sprayed, electric power for driving the discharge pump P is required, and there is a problem that power consumption increases in this respect. In the case of a DC motor-driven discharge pump that uses a battery as a power source, there has been a problem that the operation duration of the sprayer is shortened due to wasteful power consumption and the usability of the sprayer is impaired.
This invention is made | formed in view of the conventional problem which concerns, and it aims at improving the usability of a sprayer further.

The above-described problems are solved by the following inventions.
The first invention is a storage tank for storing a spray liquid such as a medicine, a discharge pump for pumping the spray liquid in the storage tank, a spray nozzle for spraying the spray liquid pumped by the discharge pump, and opening and closing the spray nozzle A sprayer equipped with a nozzle opening / closing valve that detects a flow path pressure between the discharge pump and the nozzle opening / closing valve and stops the discharge pump when the flow path pressure reaches a predetermined reference pressure. The sprayer is capable of selecting an operation mode for continuously driving the discharge pump independently of the mode and the fluctuation of the flow path pressure.
According to the first invention, the flow from the discharge pump to the nozzle opening / closing valve is closed by closing the nozzle opening / closing valve for temporarily interrupting the spraying operation in the state of switching to the former operation mode (operation mode 2). When the pressure in the passage rises to the reference pressure, the discharge pump is stopped. Thus, by eliminating the standby drive of the discharge pump when the spraying operation is interrupted, the consumption of electric power or fuel can be reduced, and the continuous operation time of the sprayer can be extended. In this respect, the usability of the sprayer is improved. be able to.
Since the power consumption can be reduced as described above, the first invention can achieve a great effect when applied to an electric sprayer using a battery as a power source.
By selecting the latter operation mode (operation mode 3), the discharge pump is continuously driven regardless of fluctuations in the flow path pressure between the discharge pump and the nozzle opening / closing valve. Therefore, the spraying operation can be performed by opening the nozzle opening / closing valve, and the spray tank can be circulated by stirring the inside of the storage tank by closing the nozzle opening / closing valve.
According to a second aspect of the present invention, there is provided the sprayer according to the first aspect, comprising a pressure switch that is turned on / off by an operation of a pressure detection mechanism caused by a change in flow path pressure, and a mode changeover switch that switches on / off operation of the pressure switch. .
According to the second invention, in the state in which the mode switch is switched to the former operation mode 2 side, when the flow path pressure rises to the reference pressure, the pressure switch is turned off by the operation of the pressure detection mechanism and the discharge pump is stopped. The When the flow path pressure becomes lower than the reference pressure, the pressure switch is turned on by the operation of the pressure detection mechanism, and the discharge pump is activated. Thereby, standby operation of the discharge pump when the spraying operation is interrupted can be avoided, and power consumption and the like can be suppressed.
In contrast, when the mode switch is switched to the latter operation mode 3 side, the discharge pump is continuously driven regardless of fluctuations in the flow path pressure between the discharge pump and the nozzle open / close valve (pressure switch ON / OFF). Thus, spraying work and stirring work can be performed.
According to a third invention, in the second invention, a power supply circuit for controlling power supply to the discharge pump is provided, and a pressure switch and a mode in which the pressure switch is switched between valid and invalid by bypassing the pressure switch are provided in the power supply circuit. A sprayer provided with a changeover switch.
According to the third aspect of the invention, when the mode changeover switch is switched to the operation mode 2 side, the pressure switch becomes effective, and the power supply circuit is turned on and off by being turned on and off. When the mode switch is switched to the operation mode 3 side, the pressure switch is disabled and the power supply circuit is turned on and off regardless of the on / off state.
A fourth invention is the maintenance function according to the third invention, wherein the power supply circuit is provided with a power switch and a maintenance switch in parallel with each other, and the discharge pump is started for a predetermined time by turning on the maintenance switch when the power switch is off. Is a sprayer.
According to the fourth invention, when performing maintenance work such as cleaning the inside of the storage tank in order to store the sprayer, the discharge pump is driven for a certain time by turning on the maintenance switch while the power switch is off. Thus, the washing water remaining in the discharge pump can be completely drained to prevent freezing and the durability of the sprayer can be improved.

1 is an overall perspective view of a sprayer according to an embodiment of the present invention. This figure has shown the state which looked at the sprayer from diagonally backward left. 1 is an overall perspective view of a sprayer according to an embodiment of the present invention. This figure has shown the state which looked at the sprayer from diagonally right back. 1 is an overall perspective view of a sprayer according to an embodiment of the present invention. This figure has shown the state which looked at the sprayer from diagonally backward left. Moreover, this figure has shown the state which open | released the opening / closing door of the battery accommodating part. 1 is an overall perspective view of a sprayer according to an embodiment of the present invention. This figure has shown the state which looked at the sprayer from diagonally right back. Moreover, this figure has shown the state which open | released the opening / closing door of the battery accommodating part. It is a longitudinal cross-sectional view of the sprayer which concerns on embodiment of this invention. This figure has shown the state which closed the door of the battery accommodating part. It is a longitudinal cross-sectional view of the sprayer which concerns on embodiment of this invention. This figure has shown the state which opened and closed the door of the battery accommodating part. It is a front view of the sprayer which concerns on embodiment of this invention. It is a perspective view of a single discharge pump. It is a longitudinal cross-sectional view of a single discharge pump. It is a figure which shows the list of the operation modes of a sprayer. It is a figure which shows the outline of a sprayer, and a power supply circuit. This figure corresponds to the operation mode 1. It is a figure which shows the outline of a sprayer, and a power supply circuit. This figure corresponds to the operation mode 2. It is a figure which shows the outline of a sprayer, and a power supply circuit. This figure corresponds to the operation mode 3. It is a figure which shows the outline of a sprayer, and a power supply circuit. This figure corresponds to the operation mode 4. It is a figure which shows the outline of a sprayer and a power supply control unit. It is a figure which shows the flowchart of the operation mode 1-2. It is a figure which shows the flowchart of the operation mode 3-4. It is a figure which shows the flowchart of the maintenance driving | operation of a discharge pump. It is a figure which shows the outline of the sprayer at the time of using a pressure sensor instead of a pressure detection mechanism and a pressure switch. It is a perspective view of an accessory storage part. (A) is a door opening / closing type accessory storage unit, (B) is a lateral rotation type accessory storage unit, (C) is a drawer type accessory storage unit, and (D) is a vertical rotation type accessory. The storage part is shown. It is a figure which shows the outline of the conventional sprayer.

Next, an embodiment of the present invention will be described with reference to FIGS. In the present embodiment, a backpack type sprayer 1 using a rechargeable battery B as a power source is illustrated. As shown in FIGS. 1 to 7, the sprayer 1 of the present embodiment includes a storage tank 10 for storing various chemicals and washing water, a drive unit 20 including a piston-type discharge pump P, and a spray nozzle 30. It has.
The storage tank 10 is a resin-made tank having chemical resistance, and an inlet for supplying the spray liquid is provided at the upper part thereof. This inlet is closed with a lid 11. Further, as shown in FIG. 2, a drainage port 12 for discharging all of the injected spray liquid is provided at the lower right side of the storage tank 10. By removing the cap 12 a of the drainage port 12, it is possible to discharge all of the spray liquid such as the medicine or the washing water that has been put into the storage tank 10.
A drive unit 20 is coupled to the lower portion of the storage tank 10. Although not shown in the drawing, a pair of left and right shoulder belts are attached to the front side of the storage tank 10. An operator can carry the sprayer 1 by placing the front surface of the storage tank 10 against the back and hanging a shoulder belt on both shoulders. In addition, in the figure, it has shown in the state installed in the floor surface F. FIG.
An inflow hose 13 (see FIG. 11) is connected near the bottom of the storage tank 10. The spray liquid in the storage tank 10 is supplied to the discharge pump P of the drive unit 20 through the inflow hose 13. 8 and 9 show this discharge pump P alone. The discharge pump P includes a DC power supply type pump motor (DC motor) 21, a speed reduction mechanism 22, and a piston portion 23. In the present embodiment, the DC motor drive type discharge pump P is illustrated, but instead, an engine type pump using an internal combustion engine as a drive source and an AC motor drive type discharge pump using an AC power source as a power source are provided. Can be applied similarly.
The rotational output of the pump motor 21 is decelerated by the speed reduction mechanism 22 and output to the piston portion 23. The piston unit 23 includes a power conversion unit 23a that converts the rotational power output from the speed reduction mechanism 22 into the reciprocating motion of the piston. A spraying force of the spray liquid is generated by the reciprocating motion of the piston. The discharge pump P is accommodated in the pump housing 24.

The speed reduction mechanism 22 includes a drive gear 22a coupled to the output shaft 21a of the pump motor 21, a driven gear 22b that meshes with the drive gear 22a, and a drive shaft 22c to which the driven gear 22b is fixed. In this embodiment, spur gears are used for the drive gear 22a and the driven gear 22b. By meshing the small-diameter drive gear 22a and the large-diameter driven gear 22b, the rotational power of the pump motor 21 is decelerated at a constant reduction ratio and output to the drive shaft 22c.
The rotational speed of the drive shaft 22c is set to a reduction ratio that is a relatively low speed rotation (for example, about 1,000 rpm to 5,000 rpm) so that the opening / closing operation of the on-off valve can smoothly follow the reciprocating operation of the piston. It is desirable.
As a reduction mechanism for reducing the rotational output of the pump motor 21, as described above, in addition to the configuration utilizing the meshing of a spur gear (spar gear), a helical gear (helical gear), a quick bevel gear (straight bevel gear) Further, meshing of spiral bevel gears (spiral bevel gears) may be used, or a configuration using a planetary gear mechanism capable of obtaining a large reduction ratio by input / output coaxial may be employed. Furthermore, instead of gear meshing, a speed reduction mechanism using a chain transmission mechanism in which a chain is stretched between the drive and driven sprockets, or a speed reduction mechanism using a belt transmission mechanism in which a belt is stretched between the drive and driven pulleys may be used. Good.
By outputting the rotation output of the pump motor 21 through the speed reduction mechanism 22 in this way, the pump motor 21 can be driven in a high-speed rotation region with little electrical loss, so that power consumption can be reduced. Since the power consumption can be reduced, the continuous usable time (working time) of the sprayer 1 using the battery B as a power source can be extended, and the usability of the sprayer 1 can be further enhanced in this respect.
In addition, the pump motor 21 can be reduced in size as compared with the case where the pump motor is directly connected to the piston portion 23 without using a speed reduction mechanism, whereby the atomizer 1 can be reduced in size and weight. .

An eccentric cam 23b of the power converter 23a is attached to the drive shaft 22c. In FIG. 9, only this eccentric cam 23b is visible. Of the displacement of the peripheral surface (cam surface) accompanying the rotation of the eccentric cam 23b, the piston reciprocates due to the displacement component in the direction orthogonal to the paper surface in FIG. A spray pressure of the spray liquid is generated by the reciprocating motion of the piston.
Instead of the piston-type discharge pump P exemplified above, for example, a rotary-type discharge pump or a diaphragm-type discharge pump can be used.
A discharge hose 25 is connected to the discharge port 23 c of the piston part 23. The discharge hose 25 is branched into a nozzle hose 33 and a return hose 14. The nozzle hose 33 is drawn from the drive unit 20 to the front side (from the back side of the user to the front side). A spray nozzle 30 that a user holds with one hand is attached to the tip of the nozzle hose 33. The spray liquid discharged from the piston portion 23 is supplied to the spray nozzle 30 through the discharge hose 25 and the nozzle hose 33.
Two types of nozzle adapters 31 and 32 of a spray type and a spray type are attached to the tip of the spray nozzle 30. At the base of the spray nozzle 30, a grip portion 35 that is gripped by the user is provided. A nozzle opening / closing valve 34 is provided on the upper side (front side) of the grip portion 35. When the lever 34a of the nozzle opening / closing valve 34 is turned to the open side, the spray liquid is sprayed from the nozzle adapters 31 and 32. When the lever 34a is turned to the closing side, the nozzle opening / closing valve 34 is closed and spraying of the spray liquid is stopped.
A return hose 14 branched from the discharge hose 25 is connected to the storage tank 10. Part or all of the spray liquid supplied from the discharge hose 25 is returned to the storage tank 10 through the return hose 14.

A pressure detection mechanism 40 is interposed in the discharge path leading to the discharge hose 25 before the discharge port 23c. The pressure detection mechanism 40 has a function of turning off the pressure switch when the flow path pressure in the discharge hose 25 reaches a predetermined reference pressure. When this pressure detection mechanism 40 is activated, the pressure switch 54 is turned off and the power supply circuit 50 is shut off. When the power supply circuit 50 is shut off, the pump motor 21 is stopped and the discharge pump P is stopped.
For this reason, for example, when the spraying operation is interrupted by operating the nozzle opening / closing valve 34 to the closed side in the activated state of the discharge pump P, the pressure detection mechanism 40 is reached when the discharge pressure in the discharge hose 25 reaches a predetermined pressure or higher. Is activated and the pumping of the spray liquid toward the nozzle hose 33 is stopped, and the discharge pump P is stopped to suppress power consumption.
When the discharge pressure in the discharge hose 25 is a certain value or less, the pressure detection mechanism 40 does not operate, so the pressure switch 54 is turned on and the power supply circuit 50 is turned on. Accordingly, when the pressure switch 54 is turned on, the pump motor 21 is restarted and the discharge pump P is started, whereby the spray liquid begins to be discharged into the discharge hose 25 again.
11 to 14 show the power supply circuit 50 of the drive unit 20. In the power supply circuit 50, the pump motor 21 of the discharge pump P uses a battery (battery pack) B as a power source. The battery B is a 36V output lithium ion battery, and can be repeatedly used by charging with a separately prepared charger. The value of current flowing through the power supply circuit 50 can be continuously changed by the variable resistor 52. By changing the output current of the battery B with the variable resistor 52, the discharge pressure of the discharge pump P can be arbitrarily changed, and thereby the discharge force of the spray liquid discharged can be arbitrarily adjusted.
An operation panel 60 is provided on the left side of the pump housing 24. The variable resistor 52 can be adjusted by rotating the strength adjustment dial 61 disposed on the operation panel 60.

The power supply circuit 50 incorporates a power switch 53, a pressure switch 54, a mode switch 55 and a maintenance switch 56. The power switch 53, the mode change switch 55, and the maintenance switch 56 are disposed on an operation panel 60 provided on the left side of the pump housing 24.
The pressure switch 54 is turned off in the pressure detection state of the pressure detection mechanism 40 and turned on in the non-detection state.
The mode switching switch 55 has a function of switching between valid and invalid of the pressure switch 54. FIG. 11 and FIG. 12 show a state in which the mode switch 55 is turned off to the pressure switch effective side. When the mode switch 55 is turned off, the pressure switch 54 is turned on / off. For this reason, when the pressure in the discharge hose 25 is not more than a certain value with the mode changeover switch 55 turned off, the pressure switch 54 is turned on and the power supply circuit 50 is turned on as shown in FIG. Therefore, the discharge pump P is activated (operation mode 1). In this operation mode 1, the spray liquid is sprayed from the spray nozzle 30 by opening the nozzle opening / closing valve 34.
Similarly, when the mode changeover switch 55 is turned off, as shown in FIG. 12, when the pressure in the discharge hose reaches a predetermined pressure or more and the pressure switch 54 is turned off, the power supply circuit 50 is cut off and the discharge pump P is stopped. (Operation mode 2). As described above, in a state where the mode changeover switch 55 is switched to the off side (pressure switch effective side), the discharge pump P is started and stopped due to the pressure fluctuation in the discharge hose 25. For this reason, in the operation mode 2, even if the spraying operation is temporarily suspended, the discharge pressure in the discharge hose 25 increases and the discharge pump P stops, so that the spray liquid is not returned to the storage tank 10. . From this, in the operation mode 2, power consumption is suppressed by stopping the discharge pump P, and power consumption is further suppressed by avoiding unnecessary stirring of the storage tank 10.
On the other hand, when the mode changeover switch 55 is turned on to the pressure switch invalid side as shown in FIGS. 13 and 14, the power supply is turned on regardless of the on / off state of the pressure switch 54 (pressure fluctuation in the discharge hose 25). The circuit 50 is always in a conductive state. For this reason, when the power switch 53 is turned on, the discharge pump P is always activated, and the spray liquid is continuously pumped into the discharge hose 25. In the normal operation state of the discharge pump P, if the user opens the nozzle opening / closing valve 34, the spray liquid can be sprayed from the spray nozzle 30 to perform the spraying operation (operation mode 3).
On the other hand, when the nozzle opening / closing valve 34 is closed in order to temporarily interrupt the spraying operation in the normal operation state of the discharge pump P, the spray liquid discharged from the discharge pump P into the discharge hose 25 passes through the return hose 14. Then, it is returned to the storage tank 10 (operation mode 4). In this operation mode 4, the spray liquid is circulated between the storage tank 10 and the discharge pump P, whereby stirring in the storage tank 10 is performed and precipitation of drug components and the like is eliminated.

The operation state of each part in the operation modes 1 to 4 is summarized in a list shown in FIG. If the mode changeover switch 55 is switched to the OFF side, the discharge pump P is started when the pressure in the discharge hose 25 does not reach a certain value, so that the spray operation is performed by opening the nozzle opening / closing valve 34. When the nozzle opening / closing valve 34 is closed and the spraying operation is temporarily interrupted, the pressure in the discharge hose 25 is increased to a certain level or more, whereby the discharge pump P is stopped and the power consumption is suppressed. (Operation mode 2). Therefore, by switching the mode changeover switch 55 to the off side, the spraying operation can be performed while suppressing the power consumption. Therefore, it is possible to extend the battery B and to save energy and power of the sprayer 1. it can.
On the other hand, if the mode changeover switch 55 is switched to the ON side, the discharge pump P is always activated regardless of the pressure fluctuation in the discharge hose 25, so that the spraying operation can be performed ( In the operation mode 3), when the nozzle opening / closing valve 34 is closed and the spraying operation is temporarily interrupted, the remaining spray liquid (so-called surplus water) discharged from the discharge pump P passes through the return hose 14 to the storage tank 10. Returned (operation mode 4). Thus, in the operation mode 4, even if the spraying operation is temporarily interrupted and the pressure in the discharge hose 25 increases, the discharge pump P is maintained in the operating state and the spray liquid is circulated. Agitation is performed to suppress precipitation of drug components and the like.

The maintenance switch 56 is incorporated in parallel with the power switch 53. The maintenance switch 56 has a built-in timer function. When the user turns on the maintenance switch 56 with the power switch 53 turned off, the power circuit 50 is turned on only after a certain time (for example, 1 minute), the pump motor 21 is started, and the discharge pump P is operated accordingly. Can do.
For example, after the spraying operation is completed, all the spray liquid in the storage tank 10 is discharged from the liquid discharge port 12, and further, the cleaning water flows into the chemical liquid tank, and the discharge pump P is activated to circulate the sprayer. A cleaning operation for cleaning 1 is performed. After the cleaning operation is completed, the cleaning water in the storage tank 10 is drained from the drain port 12, and the power switch 53 is turned off to stop the discharge pump P.
However, even when the cleaning water in the storage tank 10 is discharged and emptied, the cleaning water or the like may remain in the discharge pump P. Residual water in the discharge pump P may be frozen in cold regions or in winter. When the residual water freezes in the discharge pump P, it causes deterioration of cracks and packing of each part due to water expansion, and causes the discharge pump P and thus the durability of the sprayer 1 to be reduced. Conventionally, a discharge pump having a drain for draining this residual water has been provided, but it is necessary to drain the drain from the drain by shaking the entire sprayer. It was.
On the other hand, the sprayer 1 according to the present embodiment reliably eliminates residual water in the discharge pump P by operating the discharge pump P for a certain period of time when the power switch 53 is turned off by the maintenance switch 56. Therefore, it is not necessary to worry about freezing in a cold region, and the durability of the discharge pump P and thus the sprayer 1 can be improved.
The start-up time of the discharge pump P by turning on the maintenance switch 56 is appropriately set based on the discharge capacity per unit time of the discharge pump P and the maximum amount of liquid that can be stored in the discharge pump P. The effect (residual water freezing prevention effect) can be exhibited more reliably.

FIG. 15 shows an embodiment in which a power supply control unit 42 (hereinafter abbreviated as ECU 42) is provided in addition to the power supply circuit 50. The ECU 42 receives ON / OFF data of the power switch 53, ON / OFF data of the pressure switch 57, ON / OFF data of the mode switching switch 55, and ON / OFF data of the maintenance switch 58. Based on the output signal of the ECU 42, the pump motor 21 and thus the discharge pump P are started and stopped. 16 to 17 show an operation flow of the discharge pump P that is performed based on an output signal of the ECU 42 that is output based on various types of input data.
As shown in FIG. 16, when the user turns on the power switch 53, the ECU 42 outputs a drive signal to the pump motor 21 of the discharge pump P, whereby the discharge pump P is activated and the spray in the storage tank 10 is sprayed. Liquid is pumped. When the nozzle opening / closing valve 34 is opened in this drive state, the sprayed spray liquid is sprayed from the spray nozzle 30 (operation mode 1). On the other hand, if the nozzle open / close valve 34 is closed, the hydraulic pressure in the discharge hose 25 and the nozzle hose 33 increases. This pressure rise activates the pressure detection mechanism 40 and turns on the pressure switch 57. The pressure switch 54 is turned on and off. An ON signal of the pressure switch 57 is input to the ECU 42, and based on this, the pump motor 21 is stopped based on the output signal of the ECU 42, and therefore the discharge pump P is stopped (operation mode 2).
As shown in FIG. 17, when the user turns on the mode switch 55, the ECU 42 does not accept the output signal from the pressure switch 57. For this reason, the discharge pump P continues to be driven regardless of the fluctuation of the hydraulic pressure in the discharge hose 25 and the nozzle hose 33.
When the power switch 53 is turned on, the pump motor 21 is activated by the output signal of the ECU 42 and the discharge pump P starts operation. When the discharge pump P is activated, the spray liquid in the storage tank 10 is pumped through the discharge hose 25. At this time, the spray liquid fed by opening the nozzle opening / closing valve 34 is sprayed from the spray nozzle 30 (operation mode 3).
On the other hand, if the nozzle open / close valve 34 is closed after the discharge pump P is activated, the hydraulic pressure in the discharge hose 25 and the nozzle hose 33 increases as in the operation mode 2. However, as described above, since the ECU 42 does not accept the output signal of the pressure switch 57 as a result of the mode changeover switch 55 being turned on, the discharge pump P does not stop and continues to operate. When the discharge pump P continues to operate with the nozzle opening / closing valve 34 closed, the spray liquid circulates between the discharge pump P and the storage tank 10, thereby stirring the spray liquid in the storage tank 10. Precipitation of drug components and the like is prevented (operation mode 4).
In the ON state of the mode switch 55, the pump motor 21 is stopped by the output signal of the ECU 42 when the power switch 53 is turned OFF, and the discharge pump P is stopped.

  FIG. 18 shows a flowchart relating to the maintenance operation of the discharge pump P (residual water drainage function). In this maintenance operation, when the user turns on the maintenance switch 58, the ECU 42 determines whether the power switch 53 is in an on state (the discharge pump P is driven) or in an off state (the discharge pump P is stopped). Is determined. When it is determined that the power switch 53 is in the on state, the ECU 42 does not accept the on signal of the maintenance switch 58. When it is determined that the power switch 53 is in the OFF state, the ECU 42 receives an ON signal of the maintenance switch 58. In this case, an ON signal of the maintenance switch 58 is input to the ECU 42, and the pump motor 21 is started by the signal output from the ECU 42 based on this, and the discharge pump P is started. Thereafter, the ECU 42 determines the operation time of the discharge pump P by a timer function that measures the elapsed time after the signal is output. The operation of the discharge pump P is continued until a predetermined time has elapsed. When a certain time has elapsed, the pump motor P is stopped by the output signal, and therefore the discharge pump P is stopped.

As described above, in the OFF state of the power switch 53, the spray remaining from the discharge pump P by the function (maintenance function) of operating the discharge pump P for a certain time (for example, 1 minute) by turning on the maintenance switch 58. The liquid (residual water) can be completely drained. For this reason, the conventional problem of freezing of the residual water in the discharge pump P does not occur, whereby the durability of the discharge pump P and thus the sprayer 1 can be improved. Moreover, since the residual water does not freeze in the discharge pump P, the discharge pump P can be started smoothly when used thereafter, and the usability of the sprayer 1 can be further enhanced in this respect.
FIG. 19 shows a configuration in which a pressure sensor 41 and an ECU 42 are used in place of the pressure detection mechanism 40 and the pressure switch 57. Instead of the on / off data of the pressure switch 57, the pressure data in the discharge hose 25 detected by the pressure sensor 41 is input to the ECU. When pressure data equal to or higher than a predetermined pressure is input to the ECU 42, the pump motor 21 is stopped by the output signal, and therefore the discharge pump P is stopped. In this case, the discharge hose 25 is not closed as in the case described above. In a state where the pressure sensor 41 does not detect a discharge pressure higher than a certain pressure, the operation state of the discharge pump P is continued by the output signal of the ECU 42.
As described above, the operation state of the discharge pump P can be controlled based on the fluctuation of the discharge pressure in the discharge hose 25 by using the pressure sensor 41 instead of the pressure detection mechanism 40 having a mechanical configuration.

Next, the battery B as a power source for the sprayer 1 is accommodated in a battery accommodating portion 70 provided in the pump housing 24. As shown in FIGS. 1 to 6, the battery housing portion 70 is provided on the rear surface side of the pump housing 24. The battery housing part 70 includes an opening / closing door 71. The open / close door 71 is supported so as to be vertically rotatable via a pair of left and right hinges 71a, 71a provided at the left and right lower ends thereof. In addition, a pair of left and right leg portions 71 b and 71 b are integrally provided at a lower portion of the opening / closing door 71. Furthermore, a handle 71c is provided at the upper part of the opening / closing door 71 to be gripped during the opening / closing operation.
1, 2 and 5 show a state in which the open / close door 71 is closed. 3, 4, and 6 show a state in which the open / close door 71 is opened. On the inner surface of the open / close door 71, a battery mounting portion 72 including a slide rail for mechanically connecting the battery B and terminals for electrically connecting the battery B is provided. A battery B is mounted on the inner surface side of the open / close door 71 via the battery mounting portion 72. The battery B is a slide-mounted box battery pack, and can be attached to and detached from the battery attachment portion 72 by sliding along the inner surface of the door 71.
The open / close door 71 can be opened by rotating downward as shown in FIGS. The open / close door 71 is opened in a state where the leg portions 71b, 71b provided in the lower portion of the door 71 are grounded to the floor surface F. The open position of the open / close door 71 is set to an angle of about 45 ° with respect to the floor surface F as shown in the figure. Therefore, the battery B can be attached to the battery attachment portion 72 by sliding it downward about 45 ° with respect to the floor F, and conversely, the battery attachment portion 72 can be attached by sliding upward about 45 °. Can be removed from. As described above, the battery B is configured to be attached and detached by sliding in an oblique 45 ° direction with respect to the floor surface F. Therefore, when the sprayer 1 is installed on the floor surface F, the user has a comfortable posture. Thus, the battery B can be attached and detached, and the usability of the nebulizer 1 can be enhanced in this respect.

The open / close door 71 can be easily opened by the weight of the attached battery B. In addition, when the door 71 is open, the center of gravity G of the battery B acts as a weight for holding the door 71 in the open state, so the door 71 is held in the open position in a stable state. be able to.
On the contrary, when the door 71 is closed, the center of gravity G of the battery B is displaced to the closing side with respect to the vertical line passing through the rotation center (hinge portions 71a, 71a) of the door 71, thereby reliably closing the door. Since the center of gravity G of the battery B acts on the closing side, the open / close door 71 is reliably held at the closed position. The closed state of the open / close door 71 is locked by engaging a claw provided on the handle 71 c with the opening of the battery housing 70. When the opening / closing door 71 is locked in the closed state by the claw portion, the closed state of the opening / closing door 71 is surely maintained even by the attitude or vibration of the sprayer 1.
The battery housing part 70 opened rearward is partitioned from the discharge pump P side and the storage tank 10 side by a front wall part 73, left and right side wall parts 74 and 75, a bottom plate part 76 and a top plate part 77. For this reason, when the open / close door 71 is closed, the battery housing part 70 is in a state where the front, rear, left, right, and top and bottom are partitioned from the outside. Thus, the battery B can be shielded from the discharge pump P side and the storage tank 10 side, and from the outside (peripheral environment) of the pump housing 24. In this way, the battery B is stored in the battery accommodating portion 70 in a state shielded from the discharge pump P side etc. in all directions, so that the chemical adhesion during work, the adhesion of oil, the wetness in the rain, etc. Trouble can be prevented and the water resistance of the sprayer 1 can be increased.

Next, as shown in FIGS. 1 and 3, an accessory storage unit 80 is provided on the left side of the pump housing 24. The accessory storage unit 80 can store, for example, various types of nozzle adapters attached to the tip (discharge port) of the spray nozzle 30. The accessory storage unit 80 is provided using an empty space in the pump housing 24. The accessory storage unit 80 includes an opening / closing door 81 provided on the left side of the pump housing 24. By opening the open / close door 81, small items such as a nozzle adapter can be accommodated in the small item storage unit 80, and conversely, they can be taken out from the small item storage unit 80. Similar to the open / close door 71 of the battery housing portion 70, the open / close door 81 includes a handle 81 a and a claw portion for locking the closed state. As shown in FIG. 20A, the opening / closing door 81 is provided so as to be openable and closable by rotating in the front-rear direction via a hinge part 81b provided at the rear part.
In addition, the accessory storage unit 80, like the battery storage unit 70, has a front wall part, a rear wall part, an opening / closing door 81, a right side wall part, a bottom part, and a top plate part when the door 81 is closed. Thus, the small items are accommodated in a state separated from the discharge pump P and the storage tank 10. As a result, troubles such as oil adhesion or water wetting on small items such as the nozzle adapter accommodated in the small item accommodating portion 80 can be avoided in advance. In addition, troubles such as malfunction due to the contained small articles being mixed into the discharge pump P can be prevented. Furthermore, by storing in the accessory storage unit 80, loss of accessories such as the nozzle adapter can be prevented, and since it can be quickly prepared when necessary, the efficiency of the spraying operation can be improved. In these respects, the usability of the nebulizer 1 can be further enhanced.

As described above, the accessory storage unit can be configured to open and close by opening and closing the flat opening / closing door 81 in the horizontal direction, and various types of storage units can be applied. For example, FIG. 20B shows a pocket-type accessory housing portion 84. This pocket-type accessory housing portion 84 is provided with a pocket portion 82 having a sectoral cross section and forming an upwardly open cylindrical body so as to be pivotable in the horizontal direction via upper and lower hinge portions 82a, 82a, and its wall portion is opened and closed. 83 is provided. Small items such as a nozzle adapter can be accommodated inside the pocket portion 82 while being shielded from the discharge pump P side or the outside.
In FIG. 20C, a drawer-type accessory storage unit 85 is shown. The accessory storage unit 85 has a configuration in which a drawer 86 forming a rectangular box that is open upward is slidable in the left-right direction. Small items such as a nozzle adapter can be accommodated inside the drawer 86 while being shielded from the discharge pump P side or the outside.
In FIG. 20, (D) shows a pocket-type accessory housing part 87 as in (B). The accessory storage portion 87 shown in (D) has a configuration in which a fan-shaped pocket portion 88 that is open upward is provided so as to be pivotable up and down via hinge portions 88a and 88a provided in the lower portion thereof. Small items such as a nozzle adapter can be stored inside the fan-shaped pocket portion 88 while being shielded from the discharge pump P side or the outside.

The following various modifications can be made to the embodiment described above. For example, in the above embodiment, an example in which the return hose 14 is branched from the discharge hose 25 is shown. However, the discharge path is branched inside the discharge pump P, and the discharge pump P sprays and sprays the return hose. You may have two places of the discharge outlet to a nozzle.
Moreover, although the example using two types of nozzle adapters 31 and 32 of a spray type and an injection type was shown in said embodiment, all nozzle adapters may be the same as a spray type, and both may be the injection type. .
Furthermore, in the above embodiment, in the case of a reciprocating pump, the pump performance does not increase efficiently even if the pump rotational speed is increased, so power must be input at a low speed. Therefore, the adjustment of the output (input as viewed from the pump unit) rotational speed by the speed reduction mechanism is particularly effective.
Moreover, it is desirable that the reduction ratio when using the electric motor is about 1.5 to 3.
Also, when the shaft is displaced before and after the speed reduction mechanism, such as when using a spur gear, etc., by adjusting the shift by adjusting the speed reduction ratio, by placing other parts in the empty space, etc. The empty space in the pump housing 24 can be used efficiently.
In the above embodiment, the open / close lid 71 of the battery accommodating portion 70 is shown as an open / close type. However, the open / close lid is separable from the pump housing, and after the battery is attached to the separated open / close lid, to the pump housing The shape may be inset.
Further, in the above embodiment, an example in which the opening / closing lid 71 opens at 45 ° is shown. However, this angle is relative to the position of the hinge portion 71a of the opening / closing lid 71 in the cross section of FIG. It is good also as an angle where the gravity center G of the battery B is located on the sprayer side. According to this, even if the hinge portion 71a is in the shape of the lower part of the battery B, the open / close lid 71 can be easily closed by the dead weight of the battery B, and the battery B is in a state of moisture such as rain when the open / close lid 71 is open. The risk of exposure to can be reduced.
Furthermore, it is good also as a structure urged | biased in the direction where the opening-and-closing lid 71 closes. This can be realized by arranging, for example, a torsion spring in the hinge portions 71a, 71a.
Moreover, although the battery B of 36V was illustrated, when the battery B is a high capacity | capacitance battery with a high capacity | capacitance of 18V or more and a heavy weight, an equivalent effect can be exhibited by applying the illustrated structure.
Further, although it is desirable that the volume of the accessory storage unit 80 is large, the arrangement space for the discharge pump P, the battery B, and the like is also limited. Thus, small parts accommodating portion, it is desirable to 200cm ³ ~2000cm ³ about volume.

DESCRIPTION OF SYMBOLS 1 ... Nebulizer 10 ... Storage tank 11 ... Cover P ... Discharge pump F ... Floor 12 ... Drainage port, 12a ... Cap 13 ... Inflow hose 14 ... Return hose 20 ... Drive part 21 ... Pump motor, 21a ... Output shaft 22 ... Deceleration mechanism, 22a ... drive gear, 22b ... driven gear, 22c ... drive shaft 23 ... piston part, 23a ... power conversion part, 23b ... eccentric cam, 23c ... discharge port 24 ... pump housing 25 ... discharge hose 30 ... spray nozzle 31 32 ... Nozzle adapter 33 ... Nozzle hose 34 ... Nozzle opening / closing valve 34a ... Lever 35 ... Grip 40 ... Pressure detection mechanism 41 ... Pressure sensor 42 ... Power supply control unit (ECU)
50 ... Power supply circuit B ... Battery 52 ... Variable resistor 53 ... Power switch 54 ... Pressure switch 55 ... Mode changeover switch 56 ... Maintenance switch (built-in timer type)
57 ... Pressure switch 58 ... Maintenance switch 60 ... Operation panel 61 ... Strength adjustment dial 70 ... Battery housing part 71 ... Opening / closing door, 71a ... Hinge part, 71b ... Leg part, 71c ... Handle 72 ... Battery mounting part G ... Battery B Center of gravity 73 ... front wall part, 74 ... left side wall part, 75 ... right side wall part, 76 ... bottom plate part 77 ... top plate part 80 ... accessory storage part 81 ... open / close door, 81a ... handle, 81b ... hinge part 82 ... pocket Part, 82a ... hinge part 83 ... opening / closing door 84 ... accessory storage part (pocket type)
85 ... Accessories for small items (drawer type)
86 ... Drawer 87 ... Accessories for small items (pocket type)
88 ... Pocket part, 88a ... Hinge part

Claims (4)

A storage tank for storing a spray liquid such as a medicine, a discharge pump for pumping the spray liquid in the storage tank, a spray nozzle for spraying the spray liquid pumped by the discharge pump, and a nozzle opening and closing for opening and closing the spray nozzle A nebulizer with a valve,
An operation mode in which a flow path pressure between the discharge pump and the nozzle opening / closing valve is detected and the discharge pump is stopped when the flow path pressure reaches a predetermined reference pressure, and fluctuations in the flow path pressure The sprayer which can select the operation mode which drives the said discharge pump continuously independently from the. 2. The sprayer according to claim 1, comprising a pressure switch that is turned on / off by an operation of a pressure detection mechanism caused by fluctuations in the flow path pressure, and a mode changeover switch that switches between valid / invalid of the on / off operation of the pressure switch. The sprayer according to claim 2, further comprising a power supply circuit that controls power supply to the discharge pump, wherein the power switch is configured to bypass the pressure switch and to enable or disable the pressure switch. A nebulizer with a mode changeover switch. 4. The sprayer according to claim 3, wherein a power switch and a maintenance switch are provided in parallel with each other in the power circuit, and the discharge pump is activated for a predetermined time by turning on the maintenance switch when the power switch is off. A sprayer with a maintenance function.

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