JPS6337278B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (a) Field of Industrial Use The present invention is used in the field of squeeze-type fluid pumps that have a speed reduction device built into the pump case.

(b) Prior Art Conventionally, a squeeze-type fluid pump having a speed reducer built into the pump case is disclosed in Japanese Patent Laid-Open No. 53-36010.

That is, both ends of the stator 1 are fixed to the drum side wall 7, the left and right sides of the housing 8 provided with the rollers 17 are rotatably fitted onto the stator 1, and intermediate gears 27, 28 are installed inside the stator 1. ... are provided, and the intermediate gear 28 is meshed with the internal gear 14 of the housing 8, and the intermediate gears 27, 28... are provided at the input shaft 18.
rotates, transmits the rotation to the internal gear 14, rotates the housing 8 and revolves the roller 17,
The pumping tube is pressed by the roller to cause a pumping action.

(c) Problems to be Solved by the Invention However, in the above structure, since the internal gear is integrally formed on the inner surface of the housing that supports the roller, when the internal gear is damaged, the entire housing (support arm for supporting the roller) is damaged. are also integrally formed)
There is a problem in that the support arms and rollers have to be replaced and the repair costs are high. Even if the support arms and rollers are cut from the housing and reused in order to reduce the repair costs, extra work such as cutting and welding is required. is required, reducing work efficiency, and the housing itself cannot be reused and cannot be made sufficiently inexpensive.

Furthermore, since the housing is rotatably supported by the left and right sides of the stator, if the centers of the left and right sides of the stator are not aligned, uneven rotation of the housing, gear noise or damage due to inaccurate meshing of the internal gear, and uneven wear of the rollers may occur. Due to these problems, precision is required when manufacturing and assembling the stator, which impairs work efficiency.

Therefore, the purpose of this invention is to reduce the repair cost for damaged gears of a reduction gear, improve the efficiency of repair work, and furthermore, make the left and right supports of the rotor main body separate members, so that the rotor main body can be easily mounted in the center position. An object of the present invention is to provide a squeezed fluid pump that can perform the following functions.

(d) Means for solving the problems The present invention solves the above-mentioned problems.
A squeeze type in which a rotor main body is provided inside the pump case and a pumping tube is placed along the inner peripheral surface, and by rotating the rotor main body, a roller supported by the rotor main body presses and rolls on the pumping tube. In the fluid pump, the rotor main body includes a pair of left and right arm plates and a connecting cylinder that connects the pair of arm plates, and the connecting cylinder includes an outer cylinder having a smaller diameter than the connecting cylinder and an inner cylinder having a smaller diameter than the outer cylinder. A part of the deceleration device linked by the deceleration mechanism is installed from the other side of the rotor main body, and a support shaft is fixed to the center of the arm plate located on one side of the rotor main body, and the support shaft is fixed to the center of the arm plate located on the other side of the rotor main body. The outer cylinder of the speed reducer is bolted to the center of the arm plate, and the support shaft is rotatably supported on the pump case, and the inner cylinder of the speed reducer is fixed to the pump case. This invention relates to a squeeze-type fluid pump which rotatably supports a rotor main body.

(e) Operation By operating the motor, the power of the motor is decelerated by the reduction gear and transmitted from the arm plate on one side to the entire rotor main body, and the rollers are revolved by the rotation of the rotor main body. The pumping tube is pressed to cause pumping action.

(f) Embodiment To explain the embodiment below with reference to the drawings, 1 is a pump case formed in a sealed manner by a cylinder 2 and a pair of side walls 3, 3', and a rubber pad 4 is provided on the inner surface of the cylinder 2. has been established.

A pumping tube 5 made of an elastic member such as rubber or synthetic resin is housed in the pump case 1 along the pad 4 in a U-shape. Both ends of the pumping tube 5 extend outside, and one end is The other end is connected to a hopper (not shown), and the other end is connected to a transfer pipe (not shown).

The inside of the pumping tube 1 is maintained at a negative pressure by a vacuum pump or the like, so as to assist in maintaining the pumping tube 5 in its original shape at all times.

A rotor 6 is housed in the pumping tube 1, and the rotor 6 is rotatably supported at the center of a pump case 1, which will be described later.

The rotor main body 7 forming the main part of the rotor 6 is
It is constructed by integrally connecting a pair of arm plates 8, 8 facing each other in parallel with a gap between them by a hollow connecting cylinder 9 interposed between them. Two rollers 10, 10 are installed at the free end of the rotor main body 7 with a phase difference of 180 degrees, and when the rotor main body 7 is rotated, the rollers 10, 10 press and roll on the pumping tube 5. It's becoming like that.

A support shaft 11 is fixed to the center of the arm plate 8 located on one side of the rotor main body 7, and this support shaft 11 is rotatably supported by a bearing 12 provided at the center of the side wall 3' of the pumping tube 1. In addition, a part of the reduction gear 13 is installed in the arm plate 8 located on the other side from the other side of the rotor main body 7,
A part of the speed reducer 13 is fixed, and another part is fixed to the center of the side wall 3 of the pump case 1.

Next, the reduction gear device 13 will be explained with reference to FIGS. 2 and 3.
4. Inner cylinder 15 and both cylinders 14 having a smaller diameter than outer cylinder 14,
It consists of a deceleration mechanism linked with 15.

The inner cylinder 15 has one end attached to the center of the side wall 3 with a bolt 1.
6 and the other end extends into the connecting tube 9.
A plunger motor 17 is housed inside the inner cylinder 15, and a drive shaft 18 projects from the plunger motor 17 into the connecting cylinder 9.

The outer cylinder 14 is entirely housed in the connecting cylinder 9 of the rotor main body 7 and is fastened with bolts 19 to an arm plate 8 located on the other side of the rotor main body 7. The drive shaft 18 is rotatably supported by the inner cylinder 15 via a bearing 20, and by closing the end with a lid 21, a closed chamber 22 in which the drive shaft 18 is housed is formed. There is.

A speed reduction mechanism is installed inside the chamber 22, and the speed reduction mechanism has three shafts 24 fixed to a cylindrical rotating frame 23 with a phase difference of 120 degrees, and furthermore, a gear Z2 is attached to the shafts 24. An intermediate gear 2 in which a first gear 25... and a second gear 26... having a number of teeth Z2' are integrally formed.
7... are rotatably supported.

A part of the intermediate gears 27... is formed in the hole 2 of the rotating frame 23.
The first gear 25 protrudes from the drive shaft 18 and includes a sun gear 29 with Z1 teeth fixed to the end of the drive shaft 18 and a first internal gear 30 with Z4 teeth formed on the inner wall of the outer cylinder 14.
The second gear 26...inner cylinder 1
When the sun gear 29 is rotated with this structure, the intermediate gear 27 rotates while rotating because the second internal gear 31 is fixed. When the intermediate gear 27 rotates and revolves, the first gear 25
and the tooth ratio of the first gear 30 and the second gear 26 and the second gear
Due to the difference in the tooth ratio of the internal gear 31, the outer cylinder 14 rotates at a greatly reduced speed.

The present invention has the above-described structure. Next, the operation will be explained. First, when the plunger motor 17 is operated to rotate the sun gear 29, the intermediate gears 27 meshed with the sun gear 29 rotate. Since the second gears 31 meshing with the second gears 26 of the intermediate gears 27 are fixed, the intermediate gears 27 revolve while rotating.

When the intermediate gear 27 is rotated, the first gear 2
5 and the first internal gear 30, and the second gear 26 and the second internal gear 31, the outer cylinder 14 is rotated at a greater speed than the sun gear 29.

Due to the rotation of the outer cylinder 14, the rollers 10, 10, which are pivotally supported by the rotor main body 7, roll on the pumping tube 5, applying a continuous pressing force to the tube 5, and the pumping tube 5 When the pressure by rollers 10, 10 is released, the pumping tube 5 is restored by the restoring force due to self-elasticity and the negative pressure inside the pump case 1, and eventually the pumping tube 5 is restored by the pressing action by the rollers 10, 10, self-elasticity, and negative pressure. A pumping action is provided by the restoring action of the pump, and the fluid in the pot can be pumped to the transfer pipe.

(g) Effects of the Invention As described above, the present invention fixes a pair of arm plates that support a roller with a connecting cylinder, fixes a support shaft to one arm plate, and fixes a support shaft to the other arm plate in the connecting cylinder. Since the outer cylinder of the reduced speed reducer is bolted, the wasted space inside the pump case can be used effectively, and when the speed reducer is repaired or replaced due to damage, etc., the speed reducer can be easily removed. Since it can be taken out by simply removing the bolts from the other side of the rotor body, work efficiency such as repairs can be significantly increased, and since the rotor body can be reused as is, repairs can be carried out at low cost. .

Again, since the rotor main body is supported through a separate inner cylinder and a support shaft, it is easier to provide the rotor main body in the center position in terms of machining and assembly.

[Brief explanation of the drawing]

FIG. 1 is an overall sectional view of the present invention, FIG. 2 is a sectional view of the reduction gear device, and FIG. 3 is a sectional view taken along line AA in FIG. 2. 1 is the pump case, 5 is the pumping tube,
7 is a rotor main body, 10 and 10 are rollers, 13 is a reduction gear, 14 is an outer cylinder, and 15 is an inner cylinder.

Claims (1)

[Claims] 1. A squeezing device in which a rotor main body is provided in a pump case and a pumping tube is provided along the inner peripheral surface, and by rotating the rotor main body, a roller supported by the rotor main body presses and rolls on the pumping tube. In the type fluid pump, the rotor main body consists of a pair of left and right arm plates and a connecting cylinder that connects the pair of arm plates, and the connecting cylinder has an outer cylinder having a smaller diameter than the connecting cylinder and an inner cylinder having a smaller diameter than the outer cylinder. A part of the deceleration device which is linked by a deceleration mechanism is installed inside the rotor main body from the other side, and a support shaft is fixed to the center of the arm plate located on one side of the rotor main body, and the support shaft is fixed to the center of the arm plate located on one side of the rotor main body. The outer cylinder of the speed reducer is bolted to the center of the arm plate located at the center of the arm plate, and the support shaft is rotatably supported on the pump case, and the inner cylinder of the speed reducer is fixed to the pump case. A squeezing type fluid pump that rotatably supports a rotor main body.