KR102626228B1 - Heated Billiard Table with Improved Heating Efficiency - Google Patents

Abstract

The present invention relates to a billiard table that improves the heating efficiency of the heating element installed under the stone slab of the billiard table to ensure smooth rolling rotation of the billiard balls, and more specifically, to adjust the level of the stone slab at the crossing disposed on the upper part of the lower frame. Equipped with bolts, the adhesion device fitted to the control bolt pressurizes the heating plate into close contact with the bottom of the stone plate, eliminating the gap between the stone plate and the heating plate, thereby improving the heating efficiency of the heating plate and minimizing power consumption. This is about the heated billiard table that I ordered.

Description

Heated billiard table with improved heating efficiency {Heated Billiard Table with Improved Heating Efficiency}

The present invention relates to a billiard table that improves the heating efficiency of the heating element installed under the stone slab of the billiard table to ensure smooth rolling rotation of the billiard balls, and more specifically, to adjust the level of the stone slab at the crossing disposed on the upper part of the lower frame. Equipped with bolts, the adhesion device fitted to the control bolt pressurizes the heating plate into close contact with the bottom of the stone plate, eliminating the gap between the stone plate and the heating plate, thereby improving the heating efficiency of the heating plate and minimizing power consumption. This is about the heated billiard table that I ordered.

Generally, a billiard table consists of a lower frame that supports the billiard table, a stone plate placed on top of the lower frame, and a cushion die (denbang) that fills the four outer sides of the stone plate. Lasage is laid on the upper part of the stone plate and the cushion die is The basic structure can be seen as a structure in which a cushion made of rubber is installed, and a heating wire or heating pad is attached to the lower part of the stone slab to warm the stone slab, thereby constantly controlling the conditions of the slab and the lasage above it. Make sure the billiard ball rolls smoothly.

When the lasage on which the billiard ball rolls is heated, the moisture contained in the lasage decreases, and the deceleration force received by the billiard ball is reduced, making it more smooth and soft, and allowing the billiard ball to travel farther even when hitting the billiard ball with the same force.

However, the switch that operates the heating element or heating pad installed at the bottom of the stone slab is usually located on the counter side of the billiard room, and must be turned on 30 minutes to 1 hour before guests use the billiard table so that the stone slab is heated and the desired condition is optimal. It can be maintained as is.

However, if a guest makes a reservation in advance, the temperature of the stone plate can be raised 30 minutes or an hour in advance. However, the number of guests who make a reservation is rather small and customers come unexpectedly, so billiard rooms do not have to deal with customers who may come at any time. For this reason, the heating element or heating pad must be turned on almost all the time, which results in an increase in the billiard room's electricity bills and management/maintenance costs.

If the heating element or heating pad is turned on at all times, not only the billiard table but also the air surrounding the billiard table is heated, making the area around the billiard table hot and causing discomfort to billiard players in the summer. To solve this problem, the air conditioner is turned on. Air conditioners work against each other, further increasing energy costs.

Thermal energy supplied to heat the slabs and lasages is used to warm the air around the pool table, reducing thermal efficiency, and the air conditioner is turned on to cool the warmed air again, resulting in double energy costs.

In addition, the heating wire and heating pad heat only the central portion of the stone slab, so heat supply is not smooth to the edges of the stone slab compared to the central portion, and the heated temperature in the stone slab is not distributed uniformly and deviation occurs.

As a result, the deceleration force applied to the billiard balls rolling on the lasaji varies, making it impossible to provide consistent conditions and only adding to the confusion of the billiard player, so it cannot be considered a high-quality billiard table.

Therefore, it is possible to provide a constant deceleration force to the billiard ball by heating the entire stone slab to prevent variation by position, while also reducing the energy cost required for heating the stone slab by heating only the stone slab without heating the surrounding air. There is a need to develop a billiard table that can do this.

KR 10-2011-0075576 (A) 2011.07.06. KR 10-2359992 (B1) 2022.02.03.

In order to solve the above problem, the purpose of the present invention is to provide a heating plate for heating the stone slab from the bottom, which is provided with an insulating plate at the bottom, and is pressed upward by the stretching force of a contact device disposed at the bottom of the insulating plate, so that it is in close contact with the bottom of the stone slab. Since there is no separation space between the stone plate and the heating plate, the heat energy generated from the heating plate is transmitted directly to the stone plate without heating the surrounding air, minimizing wasted and lost heat energy and improving heating efficiency to reduce power consumption. A billiards table is provided.

Another object of the present invention is that a heating film is formed on the entire area of the heating plate and the size of the heating plate is formed to be the same as the size of the stone plate, so that when the heating plate is in close contact with the bottom of the stone plate, there is an empty space where the heating plate does not cover the stone plate. This is to provide a heated billiard table with improved heating efficiency, which prevents the slab temperature from occurring and improves uniformity by positioning the slab temperature.

Another object of the present invention is to prevent interference between the heating plate and the adjustment bolt by allowing the adjustment bolt that supports the load of the stone plate to pass through the second groove formed in the heating plate even if the heating plate is formed to the same size as the stone plate and is in close contact with the bottom of the stone plate. The goal is to provide a heated billiard table with improved heating efficiency.

Another object of the present invention is to provide a plurality of adjustment bolts for each position to adjust the inclination of the stone slab, so that even if the height of the heating plate in close contact with the bottom of the stone slab changes when adjusting the inclination of the stone slab, even at the changed height by the adhesion device, there is a gap between the stone slab and the heating plate. The purpose is to provide a heated billiard table with improved heating efficiency that adheres closely to prevent separation.

Another object of the present invention is to provide a plurality of crossings placed on the lower frame so as to cross the lower frame, so that not only the edges of the stone slab but also the central side are supported, so that deformation due to sagging due to the self-weight of the stone slab does not occur, so that it can be used for a long time. The goal is to provide a heated billiard table with improved heating efficiency that can maintain quality.

In order to achieve the above object, the present invention is disposed across the upper part of the lower frame 100 erected on the floor, and includes a crossing 200 in which a plurality of first grooves 210 are formed; An adjustment bolt 300 that protrudes upward through the first groove 210 and moves up and down in the first groove 210; A plurality of stone plates 500, the bottom of which is supported by contact with the adjustment bolt 300, and whose level is adjusted according to the elevation of the adjustment bolt 300; It receives power and generates heat, is placed in the space between the crossing 200 and the stone slab 500, is formed in the same size and shape as the stone slab 500, and is controlled by a plurality of second grooves 410 formed. A plurality of heating plates 400 through which the bolts 300 penetrate; It includes an adhesion device 310 that is fitted to the outside of the adjustment bolt 300 in a state of being pressed by the stone plate 500 and pushes the heating plate 400 with stretching force to bring it into close contact with the stone plate 500.

In addition, the lower frame 100 of the present invention includes legs 110 erected vertically from the floor; and a support groove 121 in which the crossing 200 is placed and fixed, and a support 120 disposed horizontally at the top of the bridge 110.

In addition, the heating plate 400 of the present invention includes a heating film 420 that receives power and generates heat; and an insulating plate 430 disposed below the heating film 420 to block heat emitted from the heating film 420 from being directed downward.

In addition, the heating plate 400 of the present invention is entirely in contact with the stone plate 500 at the bottom of the stone plate 500.

In addition, the stone plate 500 of the present invention is supported by the adjustment bolt 300 penetrating the heating plate 400, and the heating plate 400 is pressed only by the stretching force of the adhesion device 310.

In addition, when the inclination of the stone plate 500 supported by the adjusting bolt 300 changes due to the rotation of the adjusting bolt 300 of the present invention, the inclination of the heating plate 400 supported by the adhesion device 310 It changes in the same way as the inclination of the stone slab 500.

Additionally, the outer diameter of the contact device 310 of the present invention is formed to be larger than the diameters of the first groove 210 and the second groove 410.

The heated billiard table with improved heating efficiency according to the present invention has a heating plate that heats the stone slab from the bottom, is equipped with an insulating plate at the bottom, and is pressed upward by the stretching force of the adhesion device disposed at the bottom of the insulating plate to come into close contact with the bottom of the stone slab. Since no separation space is formed between the stone plate and the heating plate, the heat energy generated from the heating plate is transmitted directly to the stone plate without heating the surrounding air, thereby minimizing wasted and lost heat energy and reducing power consumption.

In addition, in the present invention, a heating film is formed over the entire area of the heating plate and the size of the heating plate is formed to be the same as the size of the stone plate, so that when the heating plate is in close contact with the bottom of the stone plate, an empty space is created where the heating plate cannot cover the stone plate. This has the effect of preventing differences in the temperature of the stone slab from location to location and improving uniformity.

In addition, the present invention provides heating that does not interfere with the heating plate and the control bolts because the control bolt that supports the load of the stone plate passes through the second groove formed in the heating plate even if the heating plate is formed to the same size as the stone plate and is in close contact with the bottom of the stone plate. The goal is to provide a heated billiard table with improved efficiency.

Another object of the present invention is to provide a plurality of adjustment bolts for each position to adjust the inclination of the stone slab, so that even if the height of the heating plate in close contact with the bottom of the stone slab changes when adjusting the inclination of the stone slab, even at the changed height by the adhesion device, there is a gap between the stone slab and the heating plate. It has the effect of adhering closely to prevent separation.

In addition, in the present invention, a plurality of crossings placed on the lower frame are provided so as to cross the lower frame, supporting not only the edges of the stone slab but also the center side, so that deformation due to sagging due to the self-weight of the stone slab does not occur, thereby maintaining quality even after long-term use. There is an effect that can be maintained.

Figure 1 is an exploded perspective view of a heated billiard table with improved heating efficiency of the present invention.
Figure 2 is an exploded perspective view of a heating plate in a heated billiard table with improved heating efficiency of the present invention.
Figure 3 is a plan view of the support, crossing, and heating plate combined in the heated billiard table with improved heating efficiency of the present invention.
Figure 4 is a side cross-sectional view of Figure 3.
Figure 5 is a side cross-sectional view of a heating plate in close contact with the bottom of the inclined stone slab in Figure 4.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings so that those skilled in the art can easily implement them.

Referring to FIGS. 1 to 5, the heated billiard table with improved heating efficiency according to the present invention is a billiard table that heats the stone plate 500 to reduce the moisture content of the lasage so that the billiard balls roll smoothly with less deceleration force on the lasage. Regarding,

A crossing 200 disposed across the upper part of the lower frame 100 erected on the floor and having a plurality of first grooves 210 formed thereon;

An adjustment bolt 300 that protrudes upward through the first groove 210 and moves up and down in the first groove 210;

A plurality of stone plates 500, the bottom of which is supported by contact with the adjustment bolt 300, and whose level is adjusted according to the elevation of the adjustment bolt 300;

It receives power and generates heat, is placed in the space between the crossing 200 and the stone slab 500, is formed in the same size and shape as the stone slab 500, and is controlled by a plurality of second grooves 410 formed. A plurality of heating plates 400 through which the bolts 300 penetrate;

It includes an adhesion device 310 that is fitted to the outside of the adjustment bolt 300 and pushes the heating plate 400 into close contact with the stone slab 500 using a stretching force.

The heated billiard table with improved heating efficiency according to the present invention heats the stone plate 500 to be heated with the heating plate 400, but heats the entire area of the stone plate 500 uniformly to prevent deviations, and also heats the stone plate 500 to be heated using the heating plate 400. This is a billiard table that improves heating efficiency and reduces power consumption by using the heat energy generated in 400 to heat the stone slab 500 without leaking to the outside.

In a conventional billiard table, a heating pad is placed under the stone slab 500 to heat the stone slab 500, and the heat generated by the heating pad is transferred to the stone slab 500 to warm the billiard table to an appropriate temperature. However, the lower part of the stone slab 500 Several problems occurred, such as the heating pad being crushed by the weight of the stone plate 500 and being damaged or broken.

In addition, a conventional billiard table is dually installed with a heating pad and a structure supporting the stone slab 500. In order to fully support the heavy load of the stone slab 500, a plurality of structures supporting the stone slab 500 are installed in parallel on the frame. Therefore, several compartments are created due to the structure, and a heating pad is placed within those compartments. The heating pads of this structure are not in contact with each other due to the structure supporting the stone slab 500, but are broken off and are arranged independently. The heat energy generated by the heating pad is not transmitted to the part of the stone slab 500 that is in contact with the structure, and the heating pad and There is a problem in that only the parts that are in contact or adjacent to each other are heated, so the temperature is not uniform in the stone slab 500 and a deviation occurs.

Therefore, in order to solve this problem, the present invention arranges the stone slab 500 and the heating plate 400 so that the heating plate 400, which heats the stone slab 500, does not support the load of the stone slab 500, but the stone slab 500 The horizontal of the stone plate 500 can be adjusted by being supported by the adjustment bolt 300, and the heating plate 400 is supported by the adhesion device 310 fitted to the adjustment bolt 300 so that the load of the stone plate 500 is not transmitted. No. In addition, the heating plate 400 is in close contact with the bottom surface of the stone plate 500 by the stretching force of the adhesion device 310.

Therefore, damage or failure of the heating plate 400 due to the load of the stone plate 500 does not occur, and the heating plate 400 is formed to the same size as the stone plate 500 and generates heat in close contact with the bottom of the stone plate 500, thereby generating heat energy. It is delivered directly to the stone slab 500 without leaking, thereby increasing heating efficiency and reducing power consumption.

As shown in FIG. 1, the heated billiard table with improved heating efficiency according to the present invention has a lower frame 100 built on the floor to stably support and support the billiard die 600, where the billiard balls roll, without shaking.

The lower frame 100 ensures that the billiard table is stably fixed without shaking even in situations such as when a person playing billiards puts his or her hand on it or puts his/her weight on it, and also supports the load of the stone plate 500 disposed on the upper part of the lower frame 100. It is made of materials and structures that firmly withstand.

The lower frame 100 is provided with legs 110 that stand vertically from the floor, and is provided with a support 120 that connects the legs 110 horizontally.

The legs 110 are configured to stably support the billiard table of the present invention on the floor, and are provided in several pieces, such as 4 or 6, to support the billiard table. In the drawing according to an embodiment of the present invention, the number of legs 110 is set to 6, but the number is not limited as long as it can stably support the billiard table, and two or more legs 110 are formed as one piece. It could be.

The leg 110 is erected vertically from the floor, and a support 120 is provided horizontally at the top of the leg 110. The support 120 is configured to support the crossing 200.

The billiard table is made up of rectangles with adjacent sides having different lengths. If the short side is expressed as vertical and the long side is horizontal as shown in Figure 3, the support 120 is placed in the vertical direction.

The support 120 according to an embodiment of the present invention is arranged in a total of three horizontally, one each on the left, center, and right, but is not limited to this.

The crossing 200, which will be described later, is placed and seated on the support 120, and a support groove 121 is formed to guide and fix its position. Support grooves 121 are formed at the upper edge, central side, and lower edge of each support 120, into which the crossing 200 is inserted.

The crossing 200, which is inserted into the support groove 121, supports a heavy load slab 500 at the top, and the support groove 121 acts as an external force, such as when a user puts his/her weight on it with his/her hand while playing billiards. By inserting the crossing (200) into it so that it is fixed without shaking, the billiard table becomes more stable and sturdy.

As shown in Figures 1 and 3, the crossing 200 fitted into the support groove 121 of the support 120 is formed in length in the horizontal direction of the billiard table, and is divided into three according to an embodiment of the present invention. It is provided and arranged vertically at the top edge, center side, and bottom edge. Since the support 120 is formed in a length in the vertical direction as indicated in FIG. 3, and the crossing 200 is formed in a length in the horizontal direction, the support 120 and the crossing 200 form orthogonal.

The crossing 200 is a structure that supports a high load stone slab 500. The crossing 200 disposed at the upper and lower edges of the billiard table is to support the edges of the stone slab 500, and the crossing 200 at the center of the billiard table is to support the center of the stone slab 500.

In one embodiment of the present invention, adjacent sides of the stone slab 500 are formed into rectangles with different lengths, and the longer side is placed in the vertical direction. If only the edge of the stone slab 500 is supported, the heavy stone slab 500 can be There is a problem in that the center sags down due to its own weight, causing bending deformation. Therefore, in order to prevent sagging and bending deformation, a crossing 200 having a horizontal length is further placed near the center of the billiard table to support the center of the stone slab 500 to prevent deformation of the stone slab 500.

In addition, the crossing 200 is formed with a plurality of first grooves 210 spaced apart from each other in the longitudinal direction. The first groove 210 is a hole through which an adjustment bolt 300, which will be described later, passes. The adjustment bolt 300 is inserted from the lower side of the first groove 210 and protrudes upward.

When the adjustment bolt 300 is rotated, the adjustment bolt 300 moves up and down in the first groove 210 and the length protruding upward from the first groove 210 is adjusted. As each adjustment bolt 300 is raised and lowered in the plurality of first grooves 210, the height supporting the stone slab 500 changes.

The adjustment bolt 300 is raised and lowered in the first groove 210, but does not deviate from the first groove 210. In order to prevent the adjustment bolt 300 from being separated from the first groove 210, a first groove ( 210), the head of the bolt can be formed larger than the diameter, or a nut can be installed to prevent separation, and various well-known techniques can be used in this regard.

Therefore, in a normal state when the installation of the billiard table is completed, the adjustment bolt 300 is always inserted into the first groove 210 of the crossing 200 and is slightly raised and lowered.

As shown in FIGS. 1, 4, and 5, the adjustment bolt 300 inserted into the first groove 210 supports the stone slab 500 from the lower part. Since the stone slab 500 has a high weight, a plurality of control bolts 300 are provided along the horizontal longitudinal direction of the crossing 200 in order to distribute the load it supports.

One stone slab (500) is supported by a plurality of adjustment bolts (300), and the worker adjusts each adjustment bolt (300) to raise and lower slightly to prevent the stone plate (500) from tilting to one side and maintaining it horizontally. Adjust it properly.

The load of the stone slab 500 is transmitted and supported to the floor surface through the control bolt 300, the crossing 200, and the lower frame 100.

As shown in FIGS. 1, 4, and 5, the stone slab 500 supported by the adjustment bolt 300 is heavier than other structures, so if it is formed as a single piece to cover the entire area of the billiard table, it cannot be moved or moved by the worker. It is very difficult to handle, so it is divided into multiple pieces. Several stone slabs (500) are joined together to cover the entire area of the billiard table.

One stone slab 500 is placed on the upper part of the plurality of adjustment bolts 300, and the other stone slab 500 is attached to the plurality of adjustment bolts 300 without spaces or separations so that the neighboring stone slabs 500 come into contact with each other. It is placed at the top. The bottom of the stone plate 500 is in contact with the adjustment bolt 300.

The stone slab 500 may not be perfectly horizontal when placed on the upper part of the crossing 200 depending on the roughness or flatness of the surface. By rotating the adjustment bolt 300 supporting the stone slab 500, the first By adjusting the bolt to raise and lower slightly, the upper part of the stone plate 500 is adjusted to the horizontal state as close as possible. For example, when the inclination of one stone slab 500 is biased to one side, one adjustment bolt 300 may be slightly raised and the other adjustment bolt 300 may be slightly lowered to level the plate.

Since the stone slab 500 is supported by the adjustment bolt 300, a space is formed where the crossing 200 and the stone slab 500 are spaced apart. The size of the space where the stone slab 500 and the crossing 200 are spaced apart is determined depending on how far the adjustment bolt 300 protrudes upward from the first groove 210 formed in the crossing 200. A heating plate 400 is placed in this space.

As shown in Figures 1 to 5, the heating plate 400 for heating the stone slab 500 receives power from the outside and generates heat to warm the stone slab 500. The heating plate 400 is disposed between the level crossing 200 and the stone plate 500 supported by the control bolt 300 of the level crossing 200.

The heating plate 400 is formed in the same size and shape as the stone plate 500, and is provided in the same number as the number of plates 500. One heating plate 400 covers the entire bottom area of a single stone plate 500.

Alternatively, the number of single heating plates 400 may be slightly more or less than the number of stone plates 500. In this case, when the plurality of heating plates 400 are integrated, it is preferable that the size and shape are similar to those when the plurality of stone plates 500 are integrated.

For example, a single heating plate 400 is formed in a smaller size and shape than a single stone plate 500, but the number of features of the heating plate 400 is greater than the number of features of the stone plate 500, and the heating plate 400 When placed as one body, the size and shape are the same as the plurality of stone slabs 500 arranged as one body. Therefore, the heating plate 400 and the stone plate 500 can completely overlap and adhere to each other without any gaps or margins.

Conversely, even if the size and shape of the single heating plate 400 is larger than that of the single stone plate 500, the number of features of the stone plate 500 is greater than the number of features of the heating plate 400 and the plurality of heating plates 400 connected as one body are larger than the number of features of the heating plate 400. ), as long as the size and shape are the same as the size and shape of the plurality of stone plates 500 connected as one piece.

In addition, the surfaces of the plurality of heating plates 400 are in contact with each other and are integrally connected to each other. Adjacent heating plates 400 are not spaced apart from each other. Therefore, the entire heating plate 400 is in contact with the bottom of the stone plate 500.

The heating plate 400 is equipped with a heating film 420, which is a device that receives electric power and generates heat, and an insulating plate 430 that blocks the heat energy generated by heat generated by the heating film 420 from being directed downward is installed on the heating film. It is provided at the lower part of (420).

The heating film 420 is in the form of a thin film and may tear when it receives the load of the stone plate 500, or the electric heating wire inside may break down, causing a safety accident such as a fire. Therefore, the present invention provides the heating film 420 The durability of the heating film 420 can be improved by preventing it from receiving the load of the stone plate 500.

The heating film 420 generates heat by generating heat, and this heat energy must be used to warm the stone slab 500. When used to heat the surrounding air, the heating efficiency of the stone slab 500 is lowered, so that the stone slab 500 is heated up to the set temperature. ), which increases power consumption because more power must be used to heat it.

Therefore, an insulation plate 430 is provided at the lower part of the heating film 420 to prevent thermal energy from dissipating in all directions and to minimize thermal energy leakage by directing it toward the stone slab 500.

It is preferable that there is no space between the insulation plate 430 and the heating film 420. The insulation plate 430 prevents the heat energy generated from the heating film 420 from heading toward the lower frame 100 and warming the surrounding air, and directs the heat energy only to the stone plate 500 in contact with the upper surface of the heating film 420. do.

Since the stone plate 500 and the heating plate 400 are in close contact, heat energy generated from the heating plate 400 can be intactly transmitted to the stone plate 500. Therefore, the edge of the heating plate 400 is extended further and is formed in a larger size and shape than the stone plate 500, so that even if it does not surround the edge of the stone plate 500, leaked energy is minimized, thus minimizing heat consumption of the heating plate 400. can do.

In addition, the insulation plate 430 is made of a material that is harder than the upper heating film 420, and prevents and supports the heating film 420 from sagging downward. If the heating film 420 sags due to its own weight and bends, a gap with the stone plate 500 may occur, but the insulating plate 430 prevents the heating film 420 from sagging and maintains it in a flat state. This helps ensure that the entire heating film 420 is in close contact with the stone plate 420.

In order for the adjustment bolt 300 to penetrate the heating plate 400, a plurality of second grooves 410 are formed in the heating plate 400. The heating plate 400 is disposed between the stone plate 500 and the crossing 200, and the stone plate 500 is disposed on the upper part of the heating plate 400, but the adjustment bolt 300 provided on the crossing 200 is connected to the heating plate 500. (400) Since it supports the upper stone plate 500, it passes through the heating plate 400 through the second groove 410 and comes into contact with the stone plate 500. Second grooves 410 may be formed in both the heating film 420 and the insulation plate 430. The second groove 410 is disposed at the same position as the first groove 210, so that the first groove 210 and the second groove 410 overlap each other, and the adjustment bolt 300 is connected to the first groove 210. ) and the second groove 410 at the same time.

A plurality of second grooves 410 are formed corresponding to the placement positions of the adjustment bolts 300. Since the control bolt 300 supports the stone slab 500, the heating plate 400 disposed below the stone slab 500 does not receive the load of the stone slab 500, and there is a risk of failure due to the load of the stone slab 500. There is no

As shown in Figure 4, a space is formed between the stone plate 500 and the crossing 200, and a heating plate 400 is placed in this space. The heating plate 400 is in a space where the stone plate 500 and the crossing 200 are spaced apart, and when the heating plate 400 descends downward due to its own weight and comes into close contact with the crossing 200, the heating plate 400 and The stone plates 500 are spaced apart, and the heat energy generated from the heating plate 400 cannot directly heat the stone plates 500 but warms the air, so there is no choice but to heat the stone plates 500 through indirect convection.

However, in the present invention, the heating plate 400 is brought into close contact with the bottom of the stone plate 500 in order to heat the stone plate 500 using a conduction method with higher heating efficiency than the convection method with low heating efficiency, and the heating plate 400 is weighed more than the weight of the heating plate 400. A contact device 310 with strong stretching force is provided to push the heating plate 400 from the bottom to the top.

The adhesion device 310 refers to a structure such as a spring, urethane, or rubber that has stretching force (elastic force) and contracts when pressed, and expands when the pressure is released.

The adhesion device 310 is fitted to the outside of the adjustment bolt 300. The adhesion device 310 is arranged to surround the adjustment bolt 300. The lower end of the adhesion device 310 is supported by a nut, head or crossing 200 inserted into the adjustment bolt 300, and the upper end of the adhesion device 310 is in contact with the heating plate 400.

The stone plate 500 is placed on the upper part of the heating plate 400, and the adhesion device 310 is slightly pressurized by the weight of the stone plate 500 or the heating plate 400 and is inserted into the adjustment bolt 300 in a compressed state. Lose. Therefore, the compressed adhesion device 310 can push the heating plate 400 upward with the force to expand and expand.

The outer diameter of the contact device 310 is formed to be larger than the diameters of the first groove 210 and the second groove 410, so that the contact device 310 connects the first groove 210 and the second groove 410. does not pass

The adhesion device 310 is formed with a stretching force stronger than the self-weight of the heating plate 400, preventing the heating plate 400 from compressing the adhesion device 310 and pushing the heating plate 400 upward to form the stone slab 500. ) so that it can be adhered to the bottom of the.

Since the heating plate 400 is formed with a plurality of second grooves 410 per single configuration, and the adjustment bolt 300 penetrates each second groove 410, the heating plate 400 is inserted into the adjustment bolt 300. The adhesion device 310 can push the heating plate 400 at various parts. Accordingly, the portion of the heating plate 400 that does not receive the stretching force of the adhesion device 310 is minimized, and the heating plate 500 can be completely adhered to the stone plate 500 without any gaps.

The self-weight of the stone plate 500 is supported by the adjustment bolt 300 and the self-weight of the heating plate 400 is supported by the adhesion device 310, and the heating plate 400 is pressed only by the stretching force of the adhesion device 310. Because it receives the stone plate 500, it does not damage the heating plate 400. The heating plate 400 in close contact with the bottom of the stone slab 500 receives a pressing force from the adhesion device 310, but the pressing force of the adhesion device 310 is formed to a level that does not damage the heating film 420, and furthermore, the slab ( 500), it is at an insignificant level compared to the pressing force caused by its own weight.

After the heating plate 400 is in close contact with the bottom of the stone plate 500 by the stretching force of the adhesion device 310, when heat energy is emitted from the heating film 420, contact with the surrounding air is minimized, so there is almost no leakage of heat energy and the bottom In , it is not moved to the lower part by the insulating plate 430, but can be moved to the stone plate 500 in close contact with the upper part.

The work of leveling the stone slab 500 is performed by comprehensively considering various factors such as the step of the lower frame 100 and the slope of the surface of the stone slab 500. At this time, the adjustment bolts 300 are each as shown in Figure 5. They may be located at different heights. For example, one adjustment bolt 300 may be raised, and the other adjustment bolt 300 may be placed in a lower position than the raised adjustment bolt 300. In Figure 5, the stone slab 500 is shown as having a flat upper surface, and the inclination of the stone slab 500 and the heating plate 400 is exaggerated to clearly show the height difference of the adjustment bolt 300, but in reality, the lower frame ( 100) and the level of the crossing, or the flatness of the bottom and top of the stone slab 500, the worker adjusts the height of the adjustment bolt 300 to level the upper surface of the stone slab 500. In Figure 5, the upper surface of the stone slab 500 is shown to be inclined rather than horizontal, but this is to show that the height of the adjustment bolts 300 are different from each other in order to level the upper surface of the stone slab 500.

As shown in FIG. 5, even if the height of the adjustment bolts 300 are different from each other, the heating plate 400 receives an upward pressing force by the adhesion device 310, so that it adheres to the bottom of the stone slab 500 and moves together along the slope. It slopes. In addition, while maintaining close contact, the structure of supporting the stone plate 500 and the heating plate 400 is different, so the load of the stone plate 500 is not transmitted to the heating plate 400.

As shown in Figure 1, a billiard die 600 with a lasage installed is provided on the upper part of the stone slab 500. The stone slab 500 heated by the heating film 420 dries the lassage and lowers the moisture content, thereby minimizing the deceleration force of the billiard ball and allowing it to roll smoothly.

100: Lower frame 110: Leg 120: Support 121: Support groove
200: Crossing 210: First groove 300: Control bolt 310: Close device
400: Heating plate 410: Second groove 420: Heating film 430: Insulating plate
500: Stone slab 600: Billiard die

Claims (7)

A crossing 200 disposed across the upper part of the lower frame 100 erected on the floor and having a plurality of first grooves 210 formed thereon;
An adjustment bolt 300 that protrudes upward through the first groove 210 and moves up and down in the first groove 210;
A plurality of stone slabs 500, the bottom of which is supported by contact with the adjustment bolt 300, and whose level is adjusted according to the elevation of the adjustment bolt 300;
It receives power and generates heat, is placed in the space between the crossing 200 and the stone slab 500, is formed in the same size and shape as the stone slab 500, and is controlled by a plurality of second grooves 410 formed. A plurality of heating plates 400 through which the bolts 300 penetrate;
An adhesion device 310 is fitted to the outside of the adjustment bolt 300 in a state of being pressed by the stone slab 500 and pushes the heating plate 400 with an extension force to bring it into close contact with the stone slab 500.
Heated billiard table with improved heating efficiency.
According to paragraph 1,
The lower frame 100 is
Legs 110 erected vertically from the floor surface; and
A support groove 121 is formed in which the crossing 200 is placed and fixed, and a support 120 is disposed horizontally at the top of the bridge 110.
Heated billiard table with improved heating efficiency.
According to paragraph 1,
The heating plate 400 is
Heating film 420 that receives power and generates heat; and
An insulating plate 430 disposed below the heating film 420 to block heat emitted from the heating film 420 from being directed downward.
Heated billiard table with improved heating efficiency.
According to paragraph 1,
The heating plate 400 is in full contact with the stone plate 500 at the bottom of the stone plate 500.
Heated billiard table with improved heating efficiency.
According to paragraph 1,
The stone plate 500 is supported by the adjustment bolt 300 penetrating the heating plate 400,
The heating plate 400 is pressurized only by the stretching force of the adhesion device 310.
Heated billiard table with improved heating efficiency.
According to paragraph 1,
When the inclination of the stone slab 500 supported by the adjustment bolt 300 changes due to the rotation of the adjustment bolt 300, the inclination of the heating plate 400 supported by the adhesion device 310 also changes the inclination of the stone slab 500. ) is changed to be the same as the slope of
Heated billiard table with improved heating efficiency.
According to paragraph 1,
The outer diameter of the contact device 310 is formed to be larger than the diameters of the first groove 210 and the second groove 410.
Heated billiard table with improved heating efficiency.