JPH022087B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a flow meter with sliding blades. Conventionally, as shown in FIGS. 1 and 2, a flowmeter having sliding blades has a rotor 102 rotating around a central axis 101 fixed at the center of the flowmeter, which has a small arc surface and a large arc surface. inner cylinder with 1
As the rotor 102 rotates, a plate cam 104 fixed near the center of the central shaft 101 restricts the sliding of the four blades 105 so that the blades 105 are always connected to the inlet 106 and the outlet 107. There are sliding blade flowmeters that block the flow path and continuously measure the liquid. When measuring liquid with this flowmeter, the sliding movement of the blade 105 in the radial direction is regulated by a plate cam 104 near the center of the central shaft 101. Therefore, the plate cam 104 acts on the blade 105 from only one place in the center of the blade 105, and if the frictional resistance of the upper and lower parts of the blade 105 is slightly different when the longitudinally long blade 105 advances or retreats, the blade 105 It may tilt and not move forward or backward in a stable manner. Therefore, the discharge amount changes during one revolution, resulting in a drawback of causing pulsating flow. Furthermore, when the blade 105 separates from the large arc surface and begins to retreat, the volume of the retreat of the blade 105 decreases, so when the blade 105 is on the outlet 107 side, the flow velocity changes moment by moment, causing pulsating flow. There are some drawbacks. Furthermore, this type of flowmeter requires assembly within the rotor, making assembly difficult and expensive.

The present invention aims to eliminate the above-mentioned drawbacks.
Examples will be described below with reference to the drawings. In FIGS. 3 and 4, reference numeral 1 denotes the main body of the flowmeter, which has an inlet 2 and an outlet 3. The main body 1 has a cylindrical shape, and a small arc block 44 having a small arc surface concentric with the main body 1 is attached to the inner surface of the main body 1. A small arc surface and a large arc surface are formed inside the main body 1. There is. A rotor 8 is disposed in the main body 1 with its center aligned with the main body 1 by an upper cover 6 and a lower cover 7 having bearings. It is held rotatably. The rotor 8 has the same arc as the small arc block 4 so as to rotate close to the small arc block 4, and there is a gap between the rotor 8 and the small arc block 4 to the extent that liquid does not leak. is provided.

As shown in FIGS. 5 and 6, the rotor 8 is provided with four sliding grooves 9 spaced at equal intervals in the circumferential direction and passing through in the axial direction of the rotor. The rotor 8 also has cam accommodation holes 10 at both ends, and an opening 11 that communicates with one of the adjacent sliding grooves 9. Four blades 12 are housed in the sliding groove 9 so as to sandwich the rotor shaft 18 in the radial direction of the rotor, and the blades 12 in opposing positions extend through the rotor shaft in a direction that intersects with the rotor shaft. They are connected at predetermined intervals by connecting rods 13 arranged to extend. This connecting rod 13 is screwed into one blade 12A and is locked with the other blade 12C by a pin 14, and the distance between both blades is adjustable. It is configured to come into contact with the cam surface of the plate cam. A notch 15 is bored at the top and bottom of the retreating end of the blade 12, and an inner jaw 20 and an outer jaw 21 are formed on the blade 12 with the notch 15 in between. This inner jaw part 20 protrudes from the outer jaw part 21, and this inner jaw part 20 is connected to the plate cam 1 to be described later.
7, the inlet 2, the sliding groove 9,
The structure is such that liquid does not flow between the cam storage hole 10 and the outlet 3. The inner jaw part 20 and the outer jaw part 21 hold a roller shaft, and the roller 16 is attached to this roller shaft. The rollers 16 rotate as a pair of opposing rollers, holding the plate cam 17 between them. The plate cams 17, 17 are attached to the center inside the upper cover 6 and the lower cover 7, and the rotor shaft 18 passes through the center thereof. Further, the plate cam 17 is housed in the cam housing hole 10 of the rotor 18 in close proximity to the rotor 8, so that the space near both ends of the rotor 8 is cold. This plate cam 17 has a large circular cam surface corresponding to the large circular arc surface and the small circular arc surface of the main body 1, and both cam surfaces are always connected to the roller 16.
The blades 12 are smoothly connected by cam surfaces that rotate in contact with each other, and the sliding movement of the blade 12 is regulated by these cam surfaces.

A rotation extraction mechanism (not shown) for extracting the rotation of the rotor 8 is connected to the upper side of the rotor shaft 18,
A flow rate display section 19 is connected to the rotation take-out mechanism.

In the above flowmeter, when liquid flows in from the inlet 2, dynamic pressure of the liquid is applied to the blade 12B,
When the rotor 8 rotates, the roller 16 attached to the blade 12A rolls along the plate cam 17, and the blade 12A is advanced from the rotor 8, and the adjacent blades 12A, 12B, the great circular arc surface of the main body 1, and the rotor 8 A measuring chamber is formed. When the rotor 8 rotates from this state, the blade 12B retreats within the sliding groove 9. Since the retreat of the blade 12B is restricted on both its upper and lower sides, the blade 12B
A force directed toward the center of the rotor 8 is applied equally from the plate cam 17 to both the upper and lower sides of B, and it slides smoothly.
On the other hand, after the blade 12D, which is located at a position facing the blade 12B, begins to separate from the small circular arc surface of the main body 1, an outward force acts in the opposite direction to the blade 12B, and the blade 12D moves forward in the sliding groove 9 and moves forward in the sliding groove 9. The measuring chamber begins to form.

Furthermore, when the rotor 8 rotates, the blades 12
The roller 16 reaches the small circular cam surface of the plate cam 17,
The blade 12B is completely accommodated within the sliding groove 9. Therefore, the blade 12B is connected to the small circular arc block 4.
It rotates with a small gap. When the blade 12B retreats into the sliding groove 9, the volume that accommodates the liquid on the outlet 3 side changes in volume by the amount of the blade retreat. This amount of change is discharged to the outlet 3 side through the sliding groove 9 and the opening 11, thereby preventing the flow velocity from changing due to the retreat of the blade 12.

As explained above, since the present invention is configured to restrict the sliding movement of the blade at both ends of the blade, the blade remains stable in the direction of travel even if the frictional resistance at both ends of the blade is slightly different. The edge of the blade will not get caught on the top or bottom lid. Therefore, the blade slides smoothly, there is no generation of pulsating flow on the outflow side, and there is an advantage that instrumental error is improved. Furthermore, since the present invention is configured to replenish the liquid corresponding to the change in volume of the outlet due to the retreat of the blade through the sliding groove and the opening, there is no possibility that the flow velocity changes momentarily while the blade is passing through the outlet. It also has the advantage of not causing pulsating flow. Further, since the distance between the opposing blades of the present invention is adjustable, the contact between the plate cam and the roller is perfect, and there is an advantage that no noise is generated during rotation. Further, the present invention has the advantage that since there is no contact between the main body and the blade, there is no change in instrumental error due to wear of the tip of the blade. Furthermore, since the present invention has cam storage holes on both end faces of the rotor, the plate cam can be stored inside the rotor, which not only makes the flowmeter smaller, but also reduces the weight of the rotor and reduces pressure loss due to rotor rotation. There are advantages such as Moreover, since the roller is attached to the retreating end of the blade in the present invention, both ends of the roller mounting shaft can be held, and even if the roller is subjected to diagonal force, it is better than when the mounting shaft is supported on one side. It has advantages such as durability. Further, the present invention has the advantage that the contact surface of the roller can be reduced to only one surface of the cam surface of the plate cam, and the degree of wear of the roller can be halved. Furthermore, in the present invention, since the plate cam and the rotor are arranged close to each other, there is no space at all near both sides of the rotor shaft, so that dust mixed in the liquid to be measured does not stay, but stays inside the rotor near the rotor shaft. By simply doing this, there is no possibility of dust entering into the bearing section of the rotor shaft, which has the advantage of extending the life of the bearing section.

[Brief explanation of drawings]

FIG. 1 is a cross-sectional plan view of a main part showing a conventional example, FIG. 2 is a cross-sectional view of a main part taken along line A-A in FIG. 1, FIG. 3 is a cross-sectional plan view of a main part of the present invention, and FIG. is B in Figure 3.
5 is a vertical sectional view of the rotor according to the present invention, and FIG. 6 is a cross-sectional view of the main part along the line B.
FIG. 3 is an enlarged cross-sectional view taken along the line. 1 is the main body, 2 is an inlet, 3 is an outlet, 6 is an upper cover, 7 is a lower cover, 8 is a rotor, 9 is a sliding groove, 10 is a cam storage hole, 11 is an opening, 12 is a plate, 16
is a roller, 17 is a plate cam, and 18 is a rotor shaft.

[Claims]

1. In a combination weighing device in which a drive device for a push rod for opening/closing lid actuating links of weighing hoppers, which are provided on the device frame in multiple circumferential shapes in the radial direction and each supported by a weight detector, is provided inside the weighing hopper, the device frame The push rod is provided in the clutch of the slider so as to be able to engage and disengage from the slider, which is attached to a guide frame provided in correspondence with each weighing hopper so as to be able to move forward and backward in the radial direction. A combination weighing device characterized in that the slider is connected to a drive device via a connecting rod and connected to one rotary link provided at the center of the device frame. 2. The combination weighing device according to claim 1, wherein the rotary link is capable of reciprocating rotation at a set angle. 3. A combination weighing device according to claim 1, wherein said clutch is a rack connected to a solenoid provided on said slider and is disposed opposite to a rack of said push rod. 4. The combination weighing device according to claim 1, wherein the weight detector is a load cell and is disposed radially alongside the guide frame inside the weighing hopper along the radial direction. 5 A large number of circumferential parts are provided in the device frame in the radial direction.