RU123402U1 - METAL STRUCTURE ZONES IN A TUNNEL ESCALATOR - Google Patents

Abstract

1. The metal structure of zone B of the tunnel escalator, which is a three-dimensional welded structure of a truss type made of profiled rolled products, characterized in that the extreme side truss sections adjacent to the drive zone E contain reinforcing diaphragms. 2. The metal structure of zone B according to claim 1, characterized in that the diaphragms are made of sheet steel. The metal structure of zone B according to claim 1, characterized in that the diaphragms are trapezoidal, the height of which does not exceed the height of the side truss.

Description

The utility model relates to hoisting and transport machinery and is intended for use in metal structures of tunnel escalators.

Definition of terms.

An escalator is a hoisting-and-transport device with a closed loop of a staircase for transporting people from one level to another. ¹ ( ¹ “Rules for the design and safe operation of escalators” (ПБ 10-77-94) Approved by the settlement of Gosgortekhnadzor of Russia dated 02.08.94 No. 47, Appendix 1)

Tunnel escalator - an escalator designed for installation in tunnels (galleries). ² ( ² Ibid)

Escalator zones - components of the escalator, joined during installation. Zone B - the escalator zone located above zone A, including straight guides and counter-guides. Zone B (transitional) - the upper zone of the escalator, including the upper curved section of the guides and the drive of the handrail. Zone E is the drive zone of the escalator, located after zone B. ³ ( ³ Ibid.) Zone G is thrust, designed to absorb the loads transmitted by zone E. ⁴ ( ⁴ “Maintenance instructions for the E75T, E55T escalators.” Moscow, Izd. Prospect 2006 p. 66)

The escalator metalwork is the supporting base of the escalator, on which mechanical and electrical equipment is located. The metal structure of the escalator consists of large installation units - zones. ⁵ ( ⁵ in the same place)

Known metal structure of the tunnel escalator, which is a welded structure made of high-grade steel, including a tension station, an inclined course, a drive station and bearings of the main shaft. (A.M. Oleinik, I.N. Pominov “Escalators”, M., Mechanical Engineering ”, 1973, p.148). The known design is characterized by high metal consumption and large overall dimensions.

Known closest to the claimed utility model, the metal structure of zone B of the tunnel escalator, which is a volumetric welded truss-type structure made of profile steel. (Instructions for maintenance of the E75T, E55T escalators. Moscow, Prospect Publishing House, 2006 p.66). The known metal structure of zone B does not have sufficient rigidity necessary for deep escalators. In this regard, in deep escalators to remove horizontal loads, it is necessary, in addition to the well-known metal structure of zone B, to establish an additional thrust zone G, which increases the dimensions and metal consumption of the tunnel escalator

The task to which the claimed technical solution is directed is to reduce the overall dimensions and metal consumption of the deep tunnel escalator.

The technical result achieved by solving the task is to strengthen the metal structure of zone B of the tunnel escalator.

The specified technical result is achieved by the fact that in the metal structure of zone B of the tunnel escalator, which is a volumetric welded truss type structure from profile rolled products, the extreme side truss sections adjacent to the drive zone E contain reinforcing diaphragms.

Preferably, the reinforcing diaphragms are made of sheet steel.

Preferably, each diaphragm has a trapezoid shape, the height of which does not exceed the height of the side truss.

A comparative analysis of the claimed utility model with the prototype showed that in all cases it is different from the known closest technical solution by the presence of reinforcing diaphragms in the extreme lateral truss sections adjacent to the drive zone E.

In preferred cases, the implementation of the utility model differs from the well-known, closest technical solution:

- the implementation of reinforcing diaphragms made of sheet steel;

- the implementation of diaphragms having the shape of a trapezoid, the height of which does not exceed the height of the side truss.

The presence of reinforcing diaphragms, preferably made of sheet steel, in the extreme lateral truss sections of the metal structure of zone B of the tunnel escalator adjacent to the drive zone E increases the load-bearing capacity of the metal structure of zone B and the entire escalator as a whole. This allows you to withstand horizontal loads, and does not require the use of additional zone G as part of deep escalators, which ensures a decrease in overall dimensions and metal consumption of the escalator.

The proposed utility model is illustrated in the schematic drawing shown in figure 1.

The metal structure of zone B of the tunnel escalator is a welded volumetric truss structure of profile steel. The metal structure includes lateral (right- and left-sided) truss sections 1 _{1 ... i} , 2 _{1 ... i} , each of which is formed by vertical posts 3 _i , and cross links 4 _i. Truss sections are connected by upper 5 and lower 6 belts. The extreme lateral truss sections 1 ₁ , 2 ₁ adjacent to the drive zone E (not shown in the drawing) contain reinforcing diaphragms 7 ₁ , 7 ₂ , preferably made of sheet steel. Each of the diaphragms connects the vertical struts of the truss section and has the shape of a trapezoid whose height h does not exceed the height h _{f of the} side truss.

The utility model works as follows.

The metal structure of zone B is installed as part of deep tunnel escalators between zones B and E without installing a thrust zone G (not shown in the drawing).

Claims (3)

1. The metal structure of zone B of the tunnel escalator, which is a volumetric welded truss structure of profile type, characterized in that the extreme side truss sections adjacent to the drive zone E contain reinforcing diaphragms. 2. The metal structure of zone B according to claim 1, characterized in that the diaphragms are made of sheet steel. 3. The metal structure of zone B according to claim 1, characterized in that the diaphragms have a trapezoid shape, the height of which does not exceed the height of the side truss.