CN110153366B - A laboratory sand cooling device - Google Patents

Abstract

The invention discloses a laboratory sand cooling device, which relates to the technical field of sand mold casting, comprising a frame and a box body, wherein the left and right ends of the frame are respectively rotatably connected with rotating tubes corresponding in position, the inner wall of each rotating tube is respectively rotatably connected with a rotating rod, and a water inlet channel and a water outlet channel are arranged in one of the rotating rods; the left and right ends of the box body are respectively fixedly connected with the rotating tubes; the box body comprises a main chamber, a material storage chamber arranged at the lower end of the main chamber, and a feeding pipe arranged at the upper end of the main chamber, and the position of the feeding pipe corresponds to the material storage chamber; a cooling device is arranged in the box body, and the cooling device comprises a cooling box, the left and right ends of the cooling box are respectively fixedly connected with the rotating rod, a feeding hopper is arranged at the upper end of the cooling box, a cooling plate penetrating the bottom plate of the cooling box is arranged on the bottom plate of the cooling box, a cooling cavity is arranged in the cooling plate, and a plurality of through pipes penetrating the cooling plate are evenly and fixedly connected on the cooling plate, the cooling device has the advantages of convenient use, high cooling efficiency, good effect, etc.

Description

A laboratory sand cooling device

Technical Field

The invention relates to the technical field of sand mold casting, in particular to a molding sand cooling device for laboratory use.

Background technique

Metal casting is a process of melting metal into a liquid that meets certain requirements and pouring it into a mold, and then cooling, solidifying, and cleaning to obtain a casting with a predetermined shape, size, and performance. In the process of metal casting production, molding sand is needed. Hot molding sand has a great influence on the quality of castings during the production process, so the hot molding sand needs to be cooled down. The traditional cooling method is static cooling. The existing molding sand cooling method is mainly to add a certain amount of water to the molding sand, and absorb the heat of the molding sand through the evaporation of water. These cooling equipment are large equipment, and the cost of cooling a small amount of molding sand is very high. However, there is a lack of a small-scale molding sand rapid cooling equipment in the laboratory.

Summary of the invention

The technical problem to be solved by the present invention is to provide a laboratory sand cooling device to solve the above-mentioned multiple defects caused by the prior art.

To achieve the above-mentioned purpose, the present invention provides the following technical solutions: a laboratory sand cooling device, comprising a frame and a box body, wherein the left and right ends of the frame are respectively rotatably connected with rotating tubes corresponding to the positions, and the inner wall of each rotating tube is respectively rotatably connected with a rotating rod, wherein a water inlet channel and a water outlet channel are arranged in one of the rotating rods; a rotating device for driving the rotating tube and the rotating rod to rotate is arranged on the frame; the left and right ends of the box body are respectively fixedly connected with the rotating tube, and the rotating tube passes through the side wall of the box body connected with the rotating tube; the box body comprises a main chamber, a storage chamber arranged at the lower end of the main chamber, and a feeding pipe arranged at the upper end of the main chamber, and the main chamber is connected with the feeding pipe, the storage chamber, and the feeding pipe. The material chamber is connected, and the feed pipe corresponds to the position of the storage chamber; a first valve is arranged at the inlet of the upper end of the storage chamber, and a second valve is arranged on the feed pipe; a cooling device is arranged in the box body, and the cooling device comprises a cooling box, and the left and right ends of the cooling box are respectively fixedly connected to the rotating rod, a feed hopper is arranged at the upper end of the cooling box, and the feed hopper is directly below the feed pipe, a cooling plate penetrating the bottom plate of the cooling box is arranged on the bottom plate of the cooling box, a cooling cavity is arranged in the cooling plate, a number of through pipes penetrating the cooling plate are evenly and fixedly connected to the cooling plate, and the through pipes penetrate the cooling cavity; the cooling cavity is respectively connected with the water inlet channel and the water outlet channel through water pipes.

Preferably, the rotating device comprises a rotating rod rotating device and a rotating tube rotating device.

Preferably: the rotating rod rotating device includes a support frame fixedly connected to the frame, a gear box and a first servo motor are fixedly connected to the support frame, the output shaft of the first servo motor is fixedly connected to the input shaft of the gear box, and the output shaft of the gear box is fixedly connected to one of the rotating rods.

Preferably: the rotating tube rotating device includes a second servo motor fixedly connected to the frame, a driving gear is fixedly connected to the output shaft of the second servo motor, a driven gear ring is fixedly connected to the outer wall of the rotating tube close to the second servo motor, and the driven gear ring is meshed with the driving gear.

Preferably, the connection between the lower end of the main chamber and the material storage chamber is funnel-shaped.

Preferably, the angle between the cooling box and the vertical plane after the cooling box rotates clockwise and counterclockwise is 30°-45°.

Preferably, the cooling plate is a copper plate.

The beneficial effects of adopting the above technical solution are:

The present application can drive the rotating rod to rotate through the rotating device, and then drive the cooling box to rotate. The cooling box rotates counterclockwise and clockwise in sequence, so that the molding sand in the cooling box can completely pass through the through pipe on the cooling plate; a water flow channel is formed by the water inlet channel, the cooling cavity, the water outlet channel, and the water pipe to take away the heat of the molding sand, thereby achieving the effect of cooling the molding sand;

The present application can deliver the molded sand after the initial cooling into the storage chamber by setting a box body, and deliver the high-temperature molded sand into the feed hopper through the feed pipe of the box body; then the box body can be rotated 180 degrees through the rotating pipe, so that the molded sand in the storage chamber enters the cooling box again for cooling, so as to circulate the temperature until the molded sand is completely cooled, with high cooling efficiency and convenient use;

The present application can realize fully mechanized operation by providing a rotating rod rotating device and a rotating tube rotating device, thereby improving cooling efficiency and reducing the labor intensity of operators.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a front view of a laboratory sand cooling device according to the present invention.

FIG. 2 is a front view of the cooling device of the present invention.

FIG. 3 is a top view of the cooling plate of the present invention.

FIG. 4 is a front view of the box body of the present invention after rotating 180 degrees.

Among them: frame 100, rotating device 200, supporting frame 210, first servo motor 220, gear box 230, rotating rod 240, water inlet channel 241, water outlet channel 242, rotating tube 250, driven gear ring 251, second servo motor 260, driving gear 261, box body 300, main chamber 310, storage chamber 320, first valve 330, feed pipe 340, second valve 350, cooling device 400, cooling box 410, feed hopper 420, cooling plate 430, cooling chamber 431, through pipe 432, water pipe 440.

Implementation

The embodiments of the present invention are described in detail below with reference to the accompanying drawings.

Example

As shown in Figs. 1-4, the present invention discloses a laboratory sand cooling device, comprising a frame 100 and a box 300, wherein the left and right ends of the frame 100 are respectively rotatably connected with a corresponding rotating tube 250, and the inner wall of each rotating tube 250 is respectively rotatably connected with a rotating rod 240, wherein a water inlet channel 241 and a water outlet channel 242 are arranged in one of the rotating rods 240; a rotating device for driving the rotating tube 250 and the rotating rod 240 to rotate is arranged on the frame 100; the left and right ends of the box 300 are respectively fixedly connected with the rotating tube 250, and the rotating tube 250 passes through the side wall of the box 300 connected with the rotating tube 250; the box 300 comprises a main chamber 310, a storage chamber 320 arranged at the lower end of the main chamber 310, and a feeding pipe 340 arranged at the upper end of the main chamber 310, and the main chamber 310 is communicated with the feeding pipe 340 and the storage chamber 320, and the feeding pipe 340 corresponds to the position of the storage chamber 320; a first valve 330 is provided at the upper inlet of the storage chamber 320, and a second valve 350 is provided on the feed pipe 340; a cooling device 400 is provided in the box body 300, and the cooling device 400 includes a cooling box 410, and the left and right ends of the cooling box 410 are respectively fixedly connected to the rotating rod 240, and a feed hopper 420 is provided at the upper end of the cooling box 410, and the feed hopper 420 is directly below the feed pipe 340, and a cooling plate 430 penetrating the bottom plate of the cooling box 410 is provided on the bottom plate of the cooling box 410, and a cooling cavity 431 is provided in the cooling plate 430, and a plurality of through pipes 432 penetrating the cooling plate 430 are evenly and fixedly connected to the cooling plate 430, and the through pipes 432 penetrate the cooling cavity 431; the cooling cavity 431 is respectively connected with the water inlet channel 241 and the water outlet channel 242 through the water pipe 440.

Preferably, the rotating device 200 includes a rotating rod 240 rotating device and a rotating tube 250 rotating device.

Preferably: the rotating device of the rotating rod 240 includes a support frame 210 fixedly connected to the frame 100, and a gear box 230 and a first servo motor 220 are fixedly connected to the support frame 210, the output shaft of the first servo motor 220 is fixedly connected to the input shaft of the gear box 230, and the output shaft of the gear box 230 is fixedly connected to one of the rotating rods 240.

Preferably: the rotating device of the rotating tube 250 includes a second servo motor 260 fixedly connected to the frame 100, a driving gear 261 is fixedly connected to the output shaft of the second servo motor 260, a driven gear ring 251 is fixedly connected to the outer wall of the rotating tube 250 close to the second servo motor 260, and the driven gear ring 251 is meshed with the driving gear 261.

Preferably, the connection between the lower end of the main chamber 310 and the material storage chamber 320 is funnel-shaped.

Preferably, the included angle between the cooling box 410 and the vertical plane after rotating clockwise and counterclockwise is 30°-45°.

Preferably, the cooling plate 430 is a copper plate.

The technical solution of the present invention is implemented as follows:

During use, firstly, coolant is injected into the water inlet channel 241 through an external water pump, so that the water inlet channel 241, the water pipe 440, the cooling chamber 431, and the water outlet channel 242 form a complete coolant flow path; then, the first valve 330 and the second valve 350 are opened, and then the first servo motor 220 is started. The first servo motor 220 drives the rotating rod 240 to rotate on the inner wall of the rotating tube 250 through the gear box 230, thereby driving the cooling box 410 to rotate. Driven by the first servo motor 220, the cooling box 410 first rotates counterclockwise and then clockwise, and the angle between the counterclockwise rotation and the clockwise rotation and the vertical plane is between 30 and 45 degrees, so that during the rotation of the cooling box 410, the feed pipe 340 is still facing the feed hopper 420; then, molding sand is injected into the feed pipe 340, The molding sand enters the feed hopper 420 from the feed pipe 340 and falls on the cooling plate 430 for cooling. Since the cooling box 410 reciprocates, the molding sand will fall through the through pipe 432 and enter the storage chamber 320 from the main chamber 310. When the molding sand on the cooling plate 430 completely falls into the storage chamber 320, the first valve 330 and the second valve 350 are closed, and then the second servo motor 260 is started. The second servo motor 260 drives the rotating tube 250 to rotate through the driven gear ring 251 and the driving gear 261, and then drives the box body 300 to rotate 180°, so that the storage chamber 320 is above the feed hopper 420, and then the first valve 330 is opened again, so that the molding sand in the storage chamber 320 falls into the feed hopper 420 for secondary cooling, and then the second servo motor 260 drives the box body 300 to return to its original position, and this cycle is repeated.

The above is only a preferred embodiment of the present invention. It should be pointed out that a person skilled in the art can make several modifications and improvements without departing from the inventive concept of the present invention, which all fall within the protection scope of the present invention.

Claims (7)

1. The utility model provides a molding sand cooling device for laboratory, includes frame, box, its characterized in that: the left end and the right end of the frame are respectively and rotatably connected with rotating pipes with corresponding positions, the inner wall of each rotating pipe is respectively and rotatably connected with a rotating rod, and a water inlet channel and a water outlet channel are arranged in one rotating rod; the rotating device for driving the rotating pipe and the rotating rod to rotate is arranged on the rack; the left end and the right end of the box body are respectively and fixedly connected with the rotating pipe, and the rotating pipe penetrates through the side wall of the box body connected with the rotating pipe; the box body comprises a main cavity, a stock chamber arranged at the lower end of the main cavity and a feeding pipe arranged at the upper end of the main cavity, wherein the main cavity is communicated with the feeding pipe and the stock chamber, and the feeding pipe corresponds to the stock chamber in position; a first valve is arranged at the inlet of the upper end of the stock room, and a second valve is arranged on the feeding pipe; the cooling device comprises a cooling box, the left end and the right end of the cooling box are respectively and fixedly connected with a rotating rod, a feeding hopper is arranged at the upper end of the cooling box and is right below a feeding pipe, a cooling plate penetrating through the bottom plate of the cooling box is arranged on the bottom plate of the cooling box, a cooling cavity is arranged in the cooling plate, a plurality of through pipes penetrating through the cooling plate are uniformly and fixedly connected on the cooling plate, and the through pipes penetrate through the cooling cavity; the cooling cavity is respectively communicated with the water inlet channel and the water outlet channel through water pipes.

2. A laboratory sand cooling apparatus according to claim 1, wherein said rotating means comprises a rotating rod rotating means and a rotating pipe rotating means.

3. The molding sand cooling device for a laboratory of claim 2, wherein the rotating rod rotating device comprises a supporting frame fixedly connected to the frame, a gear box and a first servo motor are fixedly connected to the supporting frame, an output shaft of the first servo motor is fixedly connected with an input shaft of the gear box, and an output shaft of the gear box is fixedly connected with one of the rotating rods.

4. The molding sand cooling device for a laboratory of claim 2, wherein the rotating device for the rotating pipe comprises a second servo motor fixedly connected to the frame, a driving gear is fixedly connected to an output shaft of the second servo motor, a driven gear ring is fixedly connected to an outer wall of the rotating pipe close to the second servo motor, and the driven gear ring is meshed with the driving gear.

5. The molding sand cooling device for laboratory of claim 1, wherein the junction of the lower end of the main chamber and the stock chamber is funnel-shaped.

6. A laboratory sand cooling device according to any one of claims 1 to 5, wherein said cooling tank is rotated clockwise and counterclockwise at an angle of 30 ° to 45 ° with respect to the vertical plane.

7. The foundry sand cooling device of claim 6 wherein the cooling plate is a copper plate.